US20230080545A1 - Distributed Additive Manufacturing Platform for Value Chain Networks - Google Patents

Distributed Additive Manufacturing Platform for Value Chain Networks Download PDF

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Publication number
US20230080545A1
US20230080545A1 US17/942,078 US202217942078A US2023080545A1 US 20230080545 A1 US20230080545 A1 US 20230080545A1 US 202217942078 A US202217942078 A US 202217942078A US 2023080545 A1 US2023080545 A1 US 2023080545A1
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United States
Prior art keywords
data
product
systems
fleet
value chain
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Application number
US17/942,078
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English (en)
Inventor
Charles Howard Cella
Andrew Cardno
Jenna Parenti
Andrew S. Locke
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Strong Force VCN Portfolio 2019 LLC
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Strong Force VCN Portfolio 2019 LLC
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Priority claimed from PCT/US2022/028633 external-priority patent/WO2022240906A1/fr
Application filed by Strong Force VCN Portfolio 2019 LLC filed Critical Strong Force VCN Portfolio 2019 LLC
Priority to US17/942,078 priority Critical patent/US20230080545A1/en
Assigned to STRONG FORCE VCN PORTFOLIO 2019, LLC reassignment STRONG FORCE VCN PORTFOLIO 2019, LLC ASSIGNMENT OF ASSIGNORS INTEREST (SEE DOCUMENT FOR DETAILS). Assignors: CARDNO, ANDREW, LOCKE, Andrew S., PARENTI, Jenna, CELLA, Charles Howard
Publication of US20230080545A1 publication Critical patent/US20230080545A1/en
Pending legal-status Critical Current

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Definitions

  • the present disclosure relates to information technology methods and systems for management of value chain network entities, including supply chain and demand management entities.
  • the present disclosure also relates to the field of enterprise management platforms, more particularly involving an edge-distributed database and query language for storing and retrieving value chain data.
  • Orders for products were fulfilled by manufacturers through a supply chain, such as depicted in FIG. 1 , where suppliers 122 in various supply environments 160 , operating production facilities 134 or acting as resellers or distributors for others, made a product 130 available at a point of origin 102 in response to an order.
  • the product 130 was passed through the supply chain, being conveyed and stored via various hauling facilities 138 and distribution facilities 134 , such as warehouses 132 , fulfillment centers 112 and delivery systems 114 , such as trucks and other vehicles, trains, and the like.
  • various hauling facilities 138 and distribution facilities 134 such as warehouses 132 , fulfillment centers 112 and delivery systems 114 , such as trucks and other vehicles, trains, and the like.
  • maritime facilities and infrastructure such as ships, barges, docks and ports provided transport over waterways between the points of origin 102 and one or more destinations 104 .
  • IoT Internet of Things
  • wearable technologies that provide metrics such as vibration data that measure the vibration signatures of important machinery, temperatures throughout the facility, motion sensors that can track throughput, asset tracking sensors and beacons to locate items, cameras and optical sensors, chemical and biological sensors, and many others.
  • wearables may provide insight into the movement, health indicators, physiological states, activity states, movements, and other characteristics of workers.
  • organizations implement CRM systems, ERP systems, operations systems, information technology systems, advanced analytics and other systems that leverage information and information technology
  • organizations have access to an increasingly wide array of other large data sets, such as marketing data, sales data, operational data, information technology data, performance data, customer data, financial data, market data, pricing data, supply chain data, and the like, including data sets generated by or for the organization and third-party data sets.
  • RFID Radio Frequency Identification
  • a method for processing a query for data stored in a distributed database includes receiving, at an edge device, the query for data stored in the distributed database from a query device. The method further includes causing, by the edge device, the query to be stored on a dynamic ledger maintained by the distributed database. The method further includes detecting, by the edge device, that summary data has been stored on the dynamic ledger. The method further includes generating, by the edge device, an approximate response to the query based on the summary data stored on the dynamic ledger. The method further includes transmitting, to the query device, the approximate response.
  • the query is an EDQL query. In some embodiments, the query specifies a shard algorithm, wherein the shard algorithm specifies a location of data stored in the distributed database. In some embodiments, the dynamic ledger is a blockchain.
  • causing the query to be stored on the dynamic ledger comprises transmitting, by the edge device, the query to an aggregator.
  • the aggregator is a blockchain node.
  • generating the approximate response to the query based on the summary data stored on the dynamic ledger further comprises generating, using the summary data, a probability distribution model for data corresponding to the query; and generating, using the probability distribution model, the approximate response.
  • the method further includes receiving a second query for data stored in the distributed database; and generating an approximate response to the second query using the probability distribution model without causing the second query to be stored on the dynamic ledger.
  • the probability distribution model is a neural network, wherein generating the probability distribution model comprises training the neural network.
  • the method further includes generating a query plan based on the received query.
  • the query plan comprises transmitting the query to other edge devices, the method further comprising transmitting the query to the other edge devices. Additionally or alternatively, the query plan comprises transmitting the query to an aggregator, the method further comprising transmitting the query to the aggregator.
  • the method further includes executing the query against edge storage connected to the edge device to obtain partial query results.
  • the approximate response to the query is further based on the partial query results.
  • the edge device is an edge device/aggregator. In some embodiments, detecting that summary data has been stored on the dynamic ledger comprises detecting that a threshold percentage of edge devices have caused summary data to be stored on the dynamic ledger.
  • the summary data is generated based on data stored at other edge devices. In some embodiments, the summary data comprises statistical data. In some embodiments, the summary data includes outlier data. In some embodiments, the data is sensor data.
  • a method for processing a query for data stored in a distributed database includes receiving, at an edge device, the query for data stored in the distributed database from a query device, wherein the query is a request for data stored at the edge device and for data stored at other edge devices.
  • the method further includes executing, by the edge device, the query to find partial query results comprising the data stored at the edge device.
  • the method further includes generating, by the edge device, statistical information based on the partial query results.
  • the method further includes determining, by the edge device, a statistical confidence associated with the partial results based on the statistical information.
  • the method further includes generating, by the edge device, an approximate response to the query based on the statistical information.
  • the method further includes transmitting the approximate response to the query device.
  • the query is an EDQL query.
  • the query specifies a shard algorithm, wherein the shard algorithm specifies a location of data stored in the distributed database.
  • the method further includes causing the statistical information to be stored on a dynamic ledger.
  • generating the approximate response to the query based on the statistical information further comprises: generating, using the statistical information, a probability distribution model for data corresponding to the query; and generating, using the probability distribution model, the approximate response.
  • the method further includes receiving a second query for data stored in the distributed database; and generating an approximate response to the second query using the probability distribution model.
  • the probability distribution model is a neural network, wherein generating the probability distribution model comprises training the neural network.
  • the method further includes generating a query plan based on the received query.
  • the approximate response to the query is further based on the partial query results.
  • the edge device is an edge device/aggregator.
  • the statistical information includes outlier data.
  • the data stored at the edge device comprises sensor data.
  • the sensor data is collected from sensors connected to the edge device. Additionally or alternatively, the sensor data is collected from sensors connected to a different edge device.
  • the distributed database comprises a mesh network of edge devices.
  • the method further includes receiving an instruction, from an aggregator, to reproduce a subset of the data stored at the edge device to a second edge device; and transmitting the subset of the data to the second edge device.
  • the query is a distributed join query.
  • generating the partial query results comprises using a reference table stored at the edge device.
  • the reference table is a distributed reference table. Additionally or alternatively, the distributed join query is executed without network overhead.
  • a method for optimizing a distributed database includes receiving, at an aggregator, one or more query logs comprising past queries received by the distributed database.
  • the method further includes generating, by the aggregator, a query prediction model based on the one or more query logs.
  • the method further includes predicting, by the aggregator, a future query using the query prediction model, wherein the future query is predicted to be received by an edge device.
  • the method further includes causing, by the aggregator, data for responding to the predicted future query to be transmitted to the edge device.
  • the data for responding to the predicted future query comprises data stored at another edge device.
  • the method further includes locating the data for responding to the predicted future query suing a sharding algorithm.
  • the sharding algorithm is a neural network algorithm. Additionally or alternatively, the sharding algorithm is a genetic algorithm. Additionally or alternatively, the sharding algorithm is a logical algorithm.
  • the data for responding to the predicted future query is summary data.
  • the summary data comprises statistical data. Additionally or alternatively, the summary data includes outlier data. Additionally or alternatively, the method further includes instructing, by the aggregator, another edge device to generate the summary data. Additionally or alternatively, the method further includes storing the summary data on a dynamic ledger maintained by the aggregator. In some of these embodiments, the dynamic ledger is a blockchain.
  • data for responding to the predicted future query is a probability distribution model.
  • the method further includes generating the probability distribution model based on data stored at another edge device.
  • the method further includes storing the probability distribution model on a dynamic ledger maintained by the aggregator.
  • the future query is an EDQL query.
  • the data for responding to the future query comprises sensor data.
  • the distributed database comprises a mesh network of edge devices.
  • the predicted future query is a distributed join query.
  • the data for responding to the predicted future query is a reference table.
  • a method for processing a query for data stored in a distributed database includes monitoring, by an edge device, one or more pending data requests stored on a dynamic ledger.
  • the method further includes detecting, by the edge device, a pending data request comprising a query for data stored in the distributed database, wherein the query is a request for data stored at the edge device and for data stored at other edge devices.
  • the method further includes executing, by the edge device, the query to find partial query results comprising the data stored at the edge device.
  • the method further includes generating, by the edge device, summary data based on the partial query results.
  • the method further includes causing, by the edge device, the summary data to be stored on the dynamic ledger.
  • the summary data comprises statistical data. In some embodiments, the summary data includes outlier data. In some embodiments, the dynamic ledger is a blockchain.
  • causing the summary data to be stored on the dynamic ledger comprises transmitting the summary data to an aggregator responsible for maintaining the dynamic ledger.
  • the aggregator is a blockchain node.
  • the method further includes generating, based on the summary data, a probability distribution model; and causing the probability distribution model to be stored on the dynamic ledger.
  • the query is an EDQL query.
  • the data stored in the distributed database comprises sensor data.
  • the distributed database comprises a mesh network of edge devices.
  • a method for processing a query for data stored in a distributed database includes receiving, at an edge device, the query for data stored in the distributed database from a query device, wherein the query comprises a distributed join referencing at least two tables, wherein the at least two tables are distributed across a plurality of edge devices comprising the edge device.
  • the method further includes obtaining, by the edge device, one or more distributed reference tables.
  • the method further includes executing, by the edge device, using the one or more distributed reference tables, the query to find partial query results comprising data stored at the edge device.
  • the method further includes generating, by the edge device, an approximate response to the query using the partial query results.
  • the query is an EDQL query. In some embodiments, the query specifies a shard algorithm, wherein the shard algorithm specifies a location of data stored in the distributed database.
  • the distributed reference tables are stored on a dynamic ledger.
  • the dynamic ledger is a blockchain. Additionally or alternatively, the method further includes causing the query to be stored on the dynamic ledger by transmitting the query to an aggregator.
  • generating the approximate response to the query using the partial query results further comprises: generating, using the partial query results a probability distribution model for data corresponding to the query; and generating, using the probability distribution model, the approximate response.
  • the probability distribution model is a neural network, wherein generating the probability distribution model comprises training the neural network.
  • the method further includes generating a query plan based on the received query.
  • the query plan comprises transmitting the query to other edge devices, the method further comprising transmitting the query to the other edge devices. Additionally or alternatively, the query plan comprises transmitting the query to an aggregator, the method further comprising transmitting the query to the aggregator.
  • the edge device is an edge device/aggregator.
  • the method further includes generating summary data based on the partial query results.
  • the summary data comprises statistical data. Additionally or alternatively, the summary data includes outlier data. Additionally or alternatively, the data is sensor data.
  • the distributed database comprises a mesh network of edge devices. In some embodiments, the distributed database comprises a fully connected network of edge devices. In some embodiments, the method further includes receiving an instruction, from an aggregator, to reproduce a subset of the data stored at the edge device to a second edge device; and transmitting the subset of the data to the second edge device. In some embodiments, the distributed join query is executed without network overhead.
  • a method for optimizing a distributed database includes receiving, at an aggregator, one or more query logs comprising past queries received by the distributed database.
  • the method further includes determining, by the aggregator, common queries received by one or more edge devices.
  • the method further includes determining, by the aggregator, that at least one edge device was not able to respond to a common query received by the at least one edge device.
  • the method further includes causing, by the aggregator, data for responding to the common query to be transmitted to the at least one edge device.
  • the data for responding to the common query comprises data stored at another edge device.
  • the method further includes locating the data for responding to the common query using a sharding algorithm.
  • the sharding algorithm is a neural network algorithm. Additionally or alternatively, the sharding algorithm is a genetic algorithm. Additionally or alternatively, the sharding algorithm is a logical algorithm.
  • the data for responding to the predicted future query is summary data.
  • the summary data comprises statistical data. Additionally or alternatively, the summary data includes outlier data. Additionally or alternatively, the method further includes instructing, by the aggregator, another edge device to generate the summary data. Additionally or alternatively, the method further includes storing the summary data on a dynamic ledger maintained by the aggregator. In some of these embodiments, the dynamic ledger is a blockchain.
  • the data for responding to the common query is a probability distribution model.
  • the method further includes generating the probability distribution model based on data stored at another edge device.
  • the method further includes storing the probability distribution model on a dynamic ledger maintained by the aggregator.
  • the common query is an EDQL query.
  • the data for responding to the common query comprises sensor data.
  • the distributed database comprises a mesh network of edge devices.
  • the common query is a distributed join query. In some of these embodiments, the data for responding to the common query is a reference table.
  • a method for prioritizing predictive model data streams includes receiving, by a first device, a plurality of predictive model data streams, wherein each predictive model data streams comprises a set of model parameters for a corresponding predictive model, wherein each predictive model is trained to predict future data values of a data source.
  • the method further includes prioritizing, by the first device, priorities to each of the plurality of predictive model data streams.
  • the method further includes selecting at least one of the predictive model data streams based on a corresponding priority.
  • the method further includes parameterizing, by the first device, a predictive model using the set of model parameters included in the selected predictive model stream.
  • the method further includes predicting, by the first device, future data values of the data source using the parameterized predictive model.
  • the selected at least one predictive model data stream is associated with a high priority. In some embodiments, the selecting comprises suppressing the predictive model data streams that were not selected based on the priorities associated with each non-selected predictive model data stream. In some embodiments, assigning priorities to each of the plurality of predictive model data streams comprises determining whether each set of model parameters is unusual. In some embodiments, assigning priorities to each of the plurality of predictive model data streams comprises determining whether each set of model parameters has changed from a previous value.
  • the set of model parameters comprise at least one vector.
  • the at least one vector comprises a motion vector associated with a robot.
  • the future data values comprise one or more future predicted locations of the robot.
  • the predictive model predicts stock levels of items, the method further comprising: detecting, based on the future data values, an upcoming supply shortage of an item; and taking action to avoid running out of the item.
  • the predictive model is a behavior analysis model, wherein the future data values indicate a predicted behavior of an entity.
  • the predictive model is an augmentation model, wherein the future data values correspond to an inoperative sensor.
  • the predictive model is a classification model, wherein the future data values indicate a predicted future state of a system comprising the one or more sensor devices.
  • the sensors are RFID sensors associated with cargo, wherein the future data values indicate future locations of the cargo.
  • the sensors are security cameras, wherein the data stream comprises motion vectors extracted from video data captured by the security cameras. In some embodiments, the sensors are vibration sensors measuring vibrations generated by machines, wherein the future data values indicate a potential need for maintenance of the machines.
  • a digital product network system includes a set of digital products each having a product processor, a product memory, and a product network interface.
  • the system further includes a product network control tower having a control tower processor, a control tower memory, and a control tower network interface.
  • the product processor and the control tower processor collectively include non-transitory instructions that program the digital product network system to: generate product level data at the product processor; transmit the product level data from the product network interface; receive the product level data at the control tower network interface; encode the product level data as a product level data structure configured to convey parameters indicated by the product level data across the set of digital products; and write the product level data structure to at least one of the product memory and the control memory.
  • the product network control tower is at least one of a remotely located server or at least one control product of the set of digital products.
  • the product processor and the control tower processor are further programmed to communicate based on a shared communication system configured for facilitating communication of the product level data from the set of digital products amongst themselves and with the product control tower.
  • the set of digital products and the product network control tower have a set of microservices and a microservices architecture.
  • the system further includes a display associated with at least one of the product network control tower or the set of digital products, wherein the digital product network system is further programmed to: generate a graphical user interface with at least one user interface display; generate the parameters of at least one digitally enabled product of the set of digital products in the at least one user interface display; and generate a proximity display of proximal digital products of the set of digital products in the at least one user interface display.
  • generating the proximity display includes generating the proximity display of proximal products that are geographically proximate.
  • the digital product network is further programmed to filter the proximal products by at least one of product type, product capability, or product brand. Additionally or alternatively, generating the proximity display includes generating the proximity display of proximal products that are proximate to one of the set of digital products by product type proximity, product capability proximity, or product brand proximity.
  • the digital product network system is further programmed to define a data integration system. In some embodiments, the digital product network system is further programmed for providing edge computation and edge intelligence configured for edge distributed decision making among the set of digital products. In some embodiments, the digital product network system is further programmed for providing edge computation and edge intelligence configured for edge network bandwidth management between or out of the set of digital products.
  • the digital product network system is further programmed to have a distributed ledger system. In some of these embodiments, the distributed ledger system wherein is a Block chain ledger. In some embodiments, the digital product network system is further programmed to have a quality management system having a system for capturing product complaints at the set of digital products. In some embodiments, the digital product network system is further programmed for: identifying a condition of the set of digital products; encoding the condition as one of the parameters of the product level data structure; and at least one of tracking or monitoring the condition across the set of digital products.
  • the digital product network system is further programmed to have a smart contract system for enabling the creation of smart contracts based on the product level data structure. In some of these embodiments, the digital product network system is further programmed for configuring the smart contracts based on a co-location-sensitive configuration of terms such that smart contract terms and conditions depend on proximity of a plurality of digital products of the set of digital products. In some embodiments, the digital product network system is further programmed to have a robotic process automation (RPA) system configured to gamify an interaction based on what digital products are in the set of digital products. In some embodiments, the digital product network system is further programmed to have a robotic process automation (RPA) system and to generate RPA processes based on use of a plurality of digital products of the set of digital products.
  • RPA robotic process automation
  • a computerized method for a processor that is at least one of a set of digital products or a product network control tower, the set of digital products each having a product processor, a product memory, and a product network interface, the product network control tower having a control tower processor, a control tower memory, and a control tower network interface.
  • the method includes generating product level data at the product processor.
  • the method further includes transmitting the product level data from the product network interface.
  • the method further includes receiving the product level data at the control tower network interface.
  • the method further includes encoding the product level data as a product level data structure configured to convey parameters indicated by the product level data across the set of digital products.
  • the method further includes writing the product level data structure to at least one of the product memory and the control memory.
  • a digital product network system includes a set of digital products each having a product memory, a product network interface, and a product processor programmed with product instructions.
  • the system further includes a product network control tower having a control tower memory, a control tower network interface, and a control tower processor programmed with control tower instructions.
  • the system further includes a digital twin system defined at least in part by at least one of the product instructions or the control tower instructions to encode a set of digital twins representing the set of digital products.
  • the digital twin system is further defined to encode hierarchical digital twins. In some embodiments, the digital twin system is further defined to encode a set of composite digital twins each made up of a set of discrete digital twins of the set of digital products. In some embodiments, the digital twin system is further defined to encode a set of digital product digital twins representing a plurality of digital products of the set of digital products. In some embodiments, the digital twin system is further defined to model traffic of moving elements in the set of digital products. In some embodiments, the digital twin system is further defined to have a playback interface for the set of digital twins wherein a user may replay data for a situation in the digital twin and observe visual representations of events related to the situation.
  • the digital twin system is further defined to: generate an adaptive user interface; and adapt for the adaptive user interface at least one of available data, features, or visual representations based on at least one of a user's association with or proximity to digital products of the set of digital products.
  • the digital twin system is further defined to manage interactions among multiple digital product digital twins of the set of digital twins.
  • the digital twin system is further defined to generate and update a self-expanding digital twin associated with the set of digital products.
  • the digital twin system is further defined to: aggregate performance data from a plurality of digital twins of the set of digital twins about a common asset type represented in the plurality of digital twins; and associate the aggregated performance data as a performance data set for retrieval.
  • the digital twin system is further defined to match owners of identical or similar products in a market for digital twin data.
  • the digital twin system is further defined to lock the set of digital twins upon detection of a security threat in a digital product of the set of digital products.
  • the digital twin system is further defined to have an in-twin marketplace. In some of these embodiments, the in-twin marketplace offers data. In some embodiments, the in-twin marketplace offers services. In some embodiments, the digital twin system is further defined to offer components. In some embodiments, the digital twin system is further defined to include application program interfaces (APIs) between the set of digital twins and marketplaces related to the set of digital products. In some embodiments, the digital twin system is further defined to have a twin store market system for providing at least one of access or rights to at least one of the set of digital twins or data associated with the set of digital twins.
  • APIs application program interfaces
  • a computerized method for a processor that is at least one of a set of digital products or a product network control tower, the set of digital products each having a product processor, a product memory, and a product network interface, the product network control tower having a control tower processor, a control tower memory, and a control tower network interface is disclosed.
  • the method includes defining a digital twin system at the processor.
  • the method further includes encoding a set of digital twins in the digital twin system, the set of digital twins representing the set of digital products.
  • the method further includes encoding a set of composite digital twins each made up of a set of discrete digital twins of the set of digital products.
  • a method for executing a quantum computing task includes providing a quantum computing system.
  • the method further includes receiving a request, from a quantum computing client, to execute a quantum computing task via the quantum computing system.
  • the method further includes executing the requested quantum computing task via the quantum computing system.
  • the method further includes returning a response related to the executed quantum computing task to the quantum computing client.
  • the quantum computing system is a quantum annealing computing system.
  • the quantum computing system supports one or more quantum computing models selected from the set of: quantum circuit model, the quantum Turing machine, spintronic computing system, adiabatic quantum computing system, one-way quantum computer, and quantum cellular automata.
  • the quantum computing system is physically implemented using an analog approach.
  • the analog approaches may be selected from the list of: quantum simulation, quantum annealing, and adiabatic quantum computation.
  • the quantum computing system is physically implemented using a digital approach.
  • the quantum computing system is an error-corrected quantum computer.
  • the quantum computing system applies trapped ions to execute the quantum computing task.
  • the quantum computing task relates to automatically discovering smart contract configuration opportunities in a value chain network.
  • the quantum-established smart contract applications are selected from the set of: booking a set of robots from a robotic fleet, booking a smart container from a smart container fleet, and executing transfer pricing agreements between subsidiaries.
  • the quantum computing task relates to risk identification or risk mitigation.
  • the quantum computing task relates to accelerated sampling from stochastic processes for risk analysis.
  • the quantum computing task relates to graph clustering analysis for anomaly or fraud detection.
  • the quantum computing task relates to generating a prediction.
  • a method for executing a quantum computing optimization task includes providing a quantum computing system.
  • the method further includes receiving a request, from a quantum computing client, to execute a quantum computing optimization task via the quantum computing system.
  • the method further includes executing the requested quantum computing optimization task via the quantum computing system.
  • the method further includes returning a response related to the executed quantum computing optimization task to the quantum computing client.
  • the quantum computing system is a quantum annealing computing system. In some embodiments, the quantum computing system is a quantum annealing computing system. In some embodiments, the quantum computing system supports one or more quantum computing models selected from the set of: quantum circuit model, the quantum Turing machine, spintronic computing system, adiabatic quantum computing system, one-way quantum computer, and quantum cellular automata.
  • the quantum computing system is physically implemented using an analog approach.
  • the analog approaches may be selected from the list of: quantum simulation, quantum annealing, and adiabatic quantum computation.
  • the quantum computing system is physically implemented using a digital approach.
  • the quantum computing system is an error-corrected quantum computer.
  • the quantum computing system applies trapped ions to execute the quantum computing task.
  • the quantum computing optimization task is a smart container-based freight transportation price optimization task.
  • the quantum computing system is configured to use q-bit-based computational methods to optimize pricing.
  • the quantum computing system is configured to optimize the design or configuration of a product, device, vehicle, or service in a value chain network.
  • a smart shipping container system includes a shipping container housing.
  • the system further includes an artificial intelligence-enabled chipset.
  • the smart shipping container system type is selected from the set of: tank container, general-purpose dry van, rolling floor container, garmentainer, ventilated container, temperature-controlled container, bulk container, open-top container, open-side container, log cradle, platform-based container, rotating container, mixing container, aviation container, automotive container, and bioprotective container.
  • the smart shipping container system is a smart package.
  • the smart shipping container system includes a mechanism to enable expanding or retracting external or internal walls, housing elements, or other internal elements, such as to increase or decrease the volume of the container or to vary the dimensions of one or more partitions of the space within the container.
  • the smart shipping container system includes a self-assembling mechanism.
  • the smart shipping container system includes a self-disassembling mechanism.
  • the smart shipping container shape is selected from the set of: rectangular, cube, sphere, cylindrical, organic-like, and biometric.
  • the smart shipping container material at least in part, is selected from the set of: corrugated weathering steel, steel alloys, stainless steel, aluminum, cast iron, concrete, ceramic material(s), other alloys, glass, other metals, plastics, plywood, bamboo, cardboard, and wood.
  • the smart shipping container system is a 3D-printed smart containers.
  • the smart shipping container system includes a 3D printer.
  • a smart shipping container system includes a shipping container housing.
  • the system further includes an artificial intelligence-enabled chipset.
  • the shipping container is configured to be self-driving.
  • the smart shipping container system type is selected from the set of: tank container, general-purpose dry van, rolling floor container, garmentainer, ventilated container, temperature-controlled container, bulk container, open-top container, open-side container, log cradle, platform-based container, rotating container, mixing container, aviation container, automotive container, and bioprotective container.
  • the smart shipping container system is a smart package.
  • the smart shipping container system includes a mechanism to enable expanding or retracting external or internal walls, housing elements, or other internal elements, such as to increase or decrease the volume of the container or to vary the dimensions of one or more partitions of the space within the container.
  • the smart shipping container system includes a self-assembling mechanism.
  • the smart shipping container system includes a self-disassembling mechanism.
  • the smart shipping container shape is selected from the set of: rectangular, cube, sphere, cylindrical, organic-like, and biometric.
  • the smart shipping container material at least in part, is selected from the set of: corrugated weathering steel, steel alloys, stainless steel, aluminum, cast iron, concrete, ceramic material(s), other alloys, glass, other metals, plastics, plywood, bamboo, cardboard, and wood.
  • the smart shipping container system is a 3D-printed smart containers.
  • the smart shipping container system includes a 3D printer.
  • a method for updating one or more properties of one or more shipping digital twins includes receiving a request to update one or more properties of one or more shipping digital twins. The method further includes retrieving the one or more shipping digital twins required to fulfill the request. The method further includes retrieving one or more dynamic models required to fulfill the request. The method further includes selecting data sources from a set of available data sources based on the one or more inputs of the one or more dynamic models. The method further includes retrieving data from selected data sources. The method further includes calculating one or more outputs using the retrieved data as one or more inputs to the one or more dynamic models. The method further includes updating one or more properties of the one or more shipping digital twins based on the output of the one or more dynamic models.
  • the digital twins are digital twins of smart containers. In some embodiments, the digital twins are digital twins of shipping environments. In some embodiments, the digital twins are digital twins of shipping entities. In some embodiments, the dynamic models take data selected from the set of vibration, temperature, pressure, humidity, wind, rainfall, tide, storm surge, cloud cover, snowfall, visibility, radiation, audio, video, image, water level, quantum, flow rate, signal power, signal frequency, motion, displacement, velocity, acceleration, lighting level, financial, cost, stock market, news, social media, revenue, worker, maintenance, productivity, asset performance, worker performance, worker response time, analyte concentration, biological compound concentration, metal concentration, and organic compound concentration data.
  • the data source is selected from the set of an Internet of Things connected device, a machine vision system, an analog vibration sensor, a digital vibration sensor, a fixed digital vibration sensor, a tri-axial vibration sensor, a single axis vibration sensor, an optical vibration sensor, and a crosspoint switch.
  • retrieving the one or more dynamic models includes identifying the one or more dynamic models based on the one or more properties indicated in the request and a respective type of the one or more digital twins.
  • the one or more dynamic models are identified using a lookup table.
  • a robot fleet management platform includes a computer-readable storage system that stores a resources data store that maintains: a robot inventory that indicates a plurality of robots that can be assigned to a robot fleet, and for each respective robot, a set of baseline features of the robot and a respective status of the robot, wherein the robot inventory of robots includes a plurality of multi-purpose robots that can be configured for different tasks and different environments; and a components inventory that indicates different components that can be provisioned to one or more multi-purpose robots, and for each component, a respective set of extended capabilities corresponding to the component and a respective status of the component.
  • the platform further includes a set of one or more processors that execute a set of computer-readable instructions.
  • the set of one or more processors collectively receive a request for a robotic fleet to perform a job.
  • the set of one or more processors collectively determine a job definition data structure based on the request, the job definition data structure defining a set of tasks that are to be performed in performance of the job.
  • the set of one or more processors collectively determine a robot fleet configuration data structure corresponding to the job based on the set of tasks and the robot inventory, wherein the robot fleet configuration data structure assigns a plurality of robots selected from the robot inventory to the set of tasks defined in the job definition data structure and the plurality of robots includes one or more assigned multi-purpose robots.
  • the set of one or more processors collectively determine a respective configuration for each respective assigned multi-purpose robot based on the respective task that is assigned to the assigned multi-purpose robot and the components inventory.
  • the set of one or more processors collectively configure the one or more assigned multi-purpose robots based on the respective configurations.
  • the set of one or more processors collectively deploy the robotic fleet to perform the job.
  • the robot inventory includes special purpose robots. In some embodiments, determining the robot fleet configuration data structure is further based on an environment of the job. In some embodiments, determining the robot fleet configuration data structure is further based on a budget for the job. In some embodiments, determining the robot fleet configuration data structure is further based on a timeline for completing the job. In some embodiments, the robot inventory includes special purpose robots and to determine the robot fleet configuration data structure is further based on an available inventory of the special purpose robots. In some embodiments, determining a respective configuration for each respective assigned multi-purpose robot is further based on an environment of the job. In some embodiments, determining a respective configuration for each respective assigned multi-purpose robot is further based on a budget for the job.
  • determining a respective configuration for each respective assigned multi-purpose robot is further based on a timeline for completing the job.
  • configuring the one or more assigned multi-purpose robots includes configuring at least one robot system selected from a list of robot systems including a robot baseline system, a module system, a robot control system, and a robot security system.
  • configuring the one or more assigned multi-purpose robots includes configuring one or more of a software robot module or a hardware robot module.
  • the hardware robot module is an interchangeable module.
  • configuring the one or more assigned multi-purpose robots task includes accessing a robot module system via at least one of a physical interface module and a control interface module.
  • configuring the one or more assigned multi-purpose robots includes configuring one or more modules of a robot baseline system, the one or more modules selected from a baseline module list including an energy storage and power distribution system, an electromechanical and electro-fluidic system, a transport system, and a vision and sensing system.
  • configuring the one or more assigned multi-purpose robots includes configuring a 3D printing system to produce at least one hardware robot module.
  • configuring the one or more assigned multi-purpose robots is based on one or more characteristics of a target operating environment.
  • a target operating environment is one or more of land-based, sea-based, submerged, in-flight, subterranean, and below-freezing ambient temperature.
  • configuring the one or more assigned multi-purpose robots includes configuring an energy storage and power distribution system to utilize two or more distinct power sources based on an aspect of one of a task and an operating environment.
  • a first distinct power source of the two or more distinct power sources is a mobile power source of the multi-purpose robot and a second distinct power source of the two or more distinct power sources is a fixed position power source that provides power to the robot via a wireless power signal.
  • configuring the one or more assigned multi-purpose robots includes configuring a propulsion system of the robot to adaptably utilize one or more legs for locomotion. In some embodiments, configuring the one or more assigned multi-purpose robots includes provisioning one or more modules identified in a job execution plan to the multi-purpose robot. In some of these embodiments, the one or more modules is a hardware module. Additionally or alternatively, the one or more modules is a software module.
  • configuring the one or more assigned multi-purpose robots includes provisioning one or more of appendages, sensor sets, chipsets, and motive adaptors to the multi-purpose robot based on at least one task in a set of target tasks for the robot that are identified in a job execution plan.
  • configuring the one or more assigned multi-purpose robots includes analyzing a job execution plan that defines a fleet of robots and configuring at least one multi-purpose robot of the fleet of robots.
  • configuring the one or more assigned multi-purpose robots includes provisioning a local manager capability that enables the multi-purpose robot to control one or more robots.
  • a method of configuring a multi-purpose robot of a fleet of robots includes receiving a request for a robotic fleet to perform a job.
  • the method further includes defining a set of tasks that are to be performed in performance of the job.
  • the method further includes assigning a plurality of robots selected from a robot inventory to the set of tasks based on the set of tasks and a robot inventory data structure that indicates a plurality of robots that can be assigned to a robot fleet, and for each respective robot, a set of baseline features of the robot and a respective status of the robot, wherein the plurality of robots includes one or more assigned multi-purpose robots that can be configured for different tasks and different environments.
  • the method further includes determining a respective configuration for each respective assigned multi-purpose robot based on the respective task that is assigned to the assigned multi-purpose robot and a components inventory that indicates different components that can be provisioned to one or more multi-purpose robots, and for each component, a respective set of extended capabilities corresponding to the component and a respective status of the component.
  • the method further includes configuring the one or more assigned multi-purpose robots based on the respective configurations.
  • the method further includes deploying the robotic fleet to perform the job.
  • the robot inventory includes special purpose robots. In some embodiments, assigning a plurality of robots selected from the robot inventory is further based on an environment of the job. In some embodiments, assigning a plurality of robots selected from the robot inventory is further based on a budget for the job. In some embodiments, assigning a plurality of robots selected from the robot inventory is further based on a timeline for completing the job. In some embodiments, the robot inventory includes special purpose robots and to assigning a plurality of robots selected from the robot inventory is further based on an available inventory of the special purpose robots. In some embodiments, determining a respective configuration for each respective assigned multi-purpose robot is further based on an environment of the job.
  • determining a respective configuration for each respective assigned multi-purpose robot is further based on a budget for the job. In some embodiments, determining a respective configuration for each respective assigned multi-purpose robot is further based on a timeline for completing the job. In some embodiments, configuring the one or more assigned multi-purpose robots includes configuring at least one robot system selected from a list of robot systems including a robot baseline system, a module system, a robot control system, and a robot security system. In some embodiments, configuring the one or more assigned multi-purpose robots includes configuring one or more of a software robot module or a hardware robot module.
  • configuring the one or more assigned multi-purpose robots task includes accessing a robot module system via at least one of a physical interface module and a control interface module.
  • configuring the one or more assigned multi-purpose robots includes configuring one or more modules of a robot baseline system, the one or more modules selected from a baseline module list including an energy storage and power distribution system, an electromechanical and electro-fluidic system, a transport system, and a vision and sensing system.
  • configuring the one or more assigned multi-purpose robots is based on one or more characteristics of a target operating environment.
  • configuring the one or more assigned multi-purpose robots includes configuring an energy storage and power distribution system to utilize two or more distinct power sources based on an aspect of one of a task and an operating environment.
  • a first distinct power source of the two or more distinct power sources is a mobile power source of the multi-purpose robot and a second distinct power source of the two or more distinct power sources is a fixed position power source that provides power to the robot via a wireless power signal.
  • configuring the one or more assigned multi-purpose robots includes configuring a propulsion system of the robot to adaptably utilize one or more legs for locomotion. In some embodiments, configuring the one or more assigned multi-purpose robots includes provisioning one or more modules identified in a job execution plan to the multi-purpose robot. In some embodiments, configuring the one or more assigned multi-purpose robots includes provisioning one or more of appendages, sensor sets, chipsets, and motive adaptors to the multi-purpose robot based on at least one task in a set of target tasks for the robot that are identified in a job execution plan.
  • configuring the one or more assigned multi-purpose robots includes analyzing a job execution plan that defines a fleet of robots and configuring at least one multi-purpose robot of the fleet of robots. In some embodiments, configuring the one or more assigned multi-purpose robots includes provisioning a local manager capability that enables the multi-purpose robot to control one or more robots.
  • a robotic fleet management platform includes a computer-readable storage system that stores a resources data store that maintains a fleet resource inventory that indicates a plurality of fleet resources that can be assigned to a robotic fleet, and for each respective fleet resource, maintenance status data including a maintenance history, a predicted maintenance need, and a preventive maintenance schedule; and a maintenance management library of fleet resource maintenance requirements that facilitates determining maintenance workflows, service actions, and service parts for at least one fleet resource of the plurality of fleet resources indicated in the fleet resource inventory.
  • the platform further includes a set of one or more processors that execute a set of computer-readable instructions.
  • the set of one or more processors collectively calculate the predicted maintenance need of a fleet resource based on anticipated component wear and anticipated component failure of one or more components of the at least one fleet resource, wherein the anticipated component wear and anticipated component failure of the one or more components is derived from machine learning-based analysis of the maintenance status data in the fleet resource inventory.
  • the set of one or more processors collectively monitor a health state of the fleet resource, wherein the health state is determined from sensor data received from the fleet resource.
  • the set of one or more processors collectively adapt the preventive maintenance schedule for the fleet resource by indicating a new preventive maintenance schedule for at least one item of maintenance for the fleet resource based on the predicted maintenance need, the health state, and the fleet resource maintenance requirements of the fleet resource.
  • the set of one or more processors collectively initiate a service action of the at least one item of maintenance for the fleet resource based on the fleet resource maintenance requirements and the new preventive maintenance schedule.
  • the set of one or more processors further predict fleet resource maintenance needs based on digital twin-based simulation of a digital twin of the at least one fleet resource.
  • the at least one fleet resource is a robotic operating unit.
  • a predictive maintenance intelligence service layer predicts at least one of the anticipated component wear or the anticipated component failure by applying a clustering algorithm to identify at least one failure pattern in a set of failure data. In some of these embodiments, the predictive maintenance intelligence service layer correlates patterns of failure to wear-down behavior present in current operational data thereby producing a pre-failure maintenance plan. In some of these embodiments, the predictive maintenance intelligence service layer adjusts a preventive maintenance plan for a robotic fleet resource based on the correlated patterns of failure for similar types of robotic fleet resources. Additionally or alternatively, the predictive maintenance intelligence service layer predicts fleet resource maintenance needs based on digital twin-based simulation of a digital twin of at least one fleet resource.
  • adapting the preventive maintenance schedule includes interacting with a fleet configuration system by sharing job-impacting fleet resource maintenance knowledge.
  • causing a service action includes configuring a set of 3D printing requirements for facilitating field maintenance of a fleet resource.
  • the 3D printing requirements are configured based on a predicted maintenance activity for the fleet resource.
  • the new preventive maintenance schedule includes scheduled field maintenance of at least one fleet resource.
  • the new preventive maintenance schedule includes scheduled repair depot-based maintenance of at least one fleet resource.
  • the at least one fleet resource is a smart container operating unit. Additionally or alternatively, the at least one fleet resource is a robotic operating unit.
  • the platform further includes a mobile maintenance vehicle.
  • the platform further includes a repair depot.
  • the platform further includes a third-party maintenance service provider.
  • adapting the preventive maintenance schedule includes adapting a maintenance schedule for at least one inactive fleet resource based on an evaluation of a maintenance need for the at least one inactive fleet resource.
  • the set of one or more processors further monitor a state of at least one fleet resource by monitoring communications of the at least one fleet resource for an indication of a maintenance need.
  • the at least one fleet resource is a robotic operating unit.
  • the indication of a maintenance need includes a lack of a heartbeat signal to a fleet resource health monitor resource.
  • the maintenance need of the at least one fleet resource includes a potential service condition.
  • the potential service condition includes one or more of reduced power output, exposure to excess ambient conditions, or a leak.
  • the set of one or more processors further deploys software-based maintenance monitoring probes to operating or supervisory software of the at least one fleet resource.
  • the probes monitor information in a data store of the at least one fleet resource that stores operating state information. Additionally or alternatively, the probes activate self-test operating modes of the at least one fleet resource. Additionally or alternatively, the probes collect data that provides indications of maintenance needs of the at least one fleet resource.
  • the set of one or more processors further deploys one or more maintenance fleet resources within one or more smart containers.
  • adapting the preventive maintenance schedule includes adapting a maintenance schedule for at least one fleet resource based on operator input regarding a state of the at least one fleet resource.
  • causing a service action includes automation of maintenance activities for the at least one fleet resource.
  • adapting the preventive maintenance schedule includes adapting a maintenance schedule for the at least one fleet resource based on artificial intelligence-based prediction of maintenance instances.
  • adapting the preventive maintenance schedule includes adapting a maintenance schedule for the at least one fleet resource based on a machine learning system that identifies new opportunities for scheduling and performing maintenance.
  • the machine learning system analyzes performance data for the at least one other robot that has been maintained for operation in certain conditions.
  • a cooling system of the other robot has been maintained prior to operating in a high temperature environment and the performance data reflects operation of the at least one other robot in the certain conditions.
  • adapting the preventive maintenance schedule includes adapting a maintenance schedule for the at least one fleet resource based on one or more of: maintenance rules established for a team, maintenance rules established for a fleet, maintenance rules established by a shipper, maintenance rules determined by a regulatory agency.
  • adapting the preventive maintenance schedule includes determining one or more of maintenance workflows, service actions, or needed parts for maintaining the at least one fleet resource based on one or more of association tables, data sets, databases, or maintenance management libraries.
  • causing a service action includes assigning a maintenance activity to a fleet resource selected from a list of fleet resources including a maintenance smart container, a human technician, and a third-party service provider.
  • causing a service action includes deploying a maintenance service that performs maintenance of the at least one fleet resource via a set of self-maintenance protocols for at least one of self-cleaning and calibrating end effector operations.
  • causing a service action includes interacting with a fleet configuration system responsive to an indication of a compromised capability of the at last one robot, the interaction resulting in a change in assignment of the at least one fleet resource based on the compromised capability.
  • causing a service action is based on an interaction with a digital twin of the at least one fleet resource being operated by a fleet intelligence service that predicts a maintenance need of the at least one fleet resource.
  • causing a service action includes coordinating maintenance activities with job scheduling to ensure that preventable interruptions due to lack of maintenance are prevented.
  • a robotic fleet resource provisioning system includes a computer-readable storage system that stores: a fleet resources data store that maintains a fleet resource inventory that indicates a plurality of fleet resources that can be provisioned as a set of fleet resources, and for each respective fleet resource, a set of features of the resource, configuration requirements of the resource, and a respective status of the resource; and a set of resource provisioning rules that are accessible to an intelligence layer to ensure that provisioned resources comply with the provisioning rules.
  • the system further includes a set of one or more processors that execute a set of computer-readable instructions. The set of one or more processors collectively receive a request for a robotic fleet to perform a job.
  • the set of one or more processors collectively determine a job definition data structure based on the request, the job definition data structure defining a set of tasks that are to be performed in performance of the job.
  • the set of one or more processors collectively determine a robotic fleet configuration data structure corresponding to the job based on the set of tasks and the fleet resource inventory, wherein the robotic fleet configuration data structure assigns a plurality of resources selected from the fleet resource inventory to the set of tasks defined in the job definition data structure.
  • the set of one or more processors collectively determine a respective provisioning configuration for each respective fleet resource based on the respective task to which the fleet resource is assigned, the set of features of the fleet resource, the configuration requirements of the fleet resource, and the respective status of the fleet resource.
  • the set of one or more processors collectively provision the respective fleet resource based on the respective provisioning configuration and the provisioning rules.
  • the set of one or more processors collectively deploy the robotic fleet to perform the job.
  • the respective status of the resource includes a general availability of the resource. In some embodiments, determining the robotic fleet configuration data structure is further based on an environment of the job. In some embodiments, determining the robotic fleet configuration data structure is further based on a budget for the job. In some embodiments, determining the robotic fleet configuration data structure is further based on a timeline for completing the job. In some embodiments, the fleet resource inventory includes one or more types of robots and to determine the robotic fleet configuration data structure is further based on an available inventory of the one or more types of robots. In some embodiments, determining a provisioning configuration for each respective fleet resource is further based on an environment of the job.
  • determining a provisioning configuration for each respective fleet resource is further based on a budget for the job. In some embodiments, determining a provisioning configuration for each respective assigned fleet resource is further based on a timeline for completing the job. In some embodiments, the fleet resource inventory includes computing resources selected from a list of computing resources comprising on-robot computing resources, robot operating unit-local fleet-controlled computing resources, cloud based computing resources, computing modules, or computing chips.
  • provisioning the respective fleet resource includes provisioning one or more of a software robot module or a hardware robot module.
  • the hardware robot module is an interchangeable module.
  • the fleet resource inventory includes a plurality of digital resources.
  • provisioning a respective one of the plurality of digital resources includes one or more of software update pushing, resource access credentialing, or fleet resource data storage configuration, allocation, or utilization.
  • provisioning a respective fleet resource includes provisioning a consumable resource sourced from at least one of a specialized supply chain, a job requestor resource supply, a fleet-specific stockpile, a job-specific stockpile, or a fleet team-specific stockpile.
  • provisioning the respective fleet resource is based on one or more characteristics of a target operating environment.
  • a target operating environment is one or more of land-based, sea-based, submerged, in-flight, subterranean, and below-freezing ambient temperature.
  • provisioning the respective fleet resource includes 3D printing the respective resource for provisioning. In some embodiments, provisioning the respective fleet resource is based on terms of a smart contract that constrains provisioning of fleet resources. In some embodiments, the fleet resource inventory includes platform resources and to provision the respective fleet resource includes provisioning at least one platform resource selected from a list of platform resources including computing resources, a fleet configuration system, a platform intelligence layer, a platform data processing system, and a fleet security system. In some of these embodiments, determining a robotic fleet configuration data structure is further based on a negotiated charge for provisioning a platform resource. Additionally or alternatively, determining a robotic fleet configuration data structure includes a negotiation workflow for acceptance of the job request.
  • provisioning the respective fleet resource includes provisioning one or more fleet resources identified in a job execution plan. In some embodiments, provisioning the respective fleet resource includes provisioning one or more of appendages, sensor sets, chipsets, and motive adaptors to a robot based on at least one task in a set of target tasks for the robot that are identified in a job execution plan. In some embodiments, provisioning the respective fleet resource includes analyzing a job execution plan that defines resources for a fleet of robots for performing at least one task. In some embodiments, the set of one or more processors execute the set of computer-readable instructions cooperatively with at least one of a fleet configuration system, a fleet resource scheduling system, a fleet security system, and a fleet utilization system.
  • a method of provisioning robotic fleet resources includes receiving a request for a robotic fleet to perform a job.
  • the method further includes determining a job definition data structure based on the request, the job definition data structure defining a set of tasks that are to be performed in performance of the job.
  • the method further includes determining a robotic fleet configuration data structure corresponding to the job based on the set of tasks and a fleet resource inventory that indicates a plurality of fleet resources, and for each respective fleet resource, a set of features of the resource, configuration requirements of the resource, and a respective status of the resource, wherein the robotic fleet configuration data structure assigns a plurality of resources selected from the fleet resource inventory to the set of tasks defined in the job definition data structure.
  • the method further includes determining a respective provisioning configuration for each respective fleet resource based on the respective task to which the fleet resource is assigned, the set of features of the fleet resource, the configuration requirements of the fleet resource, and the respective status of the fleet resource.
  • the method further includes provisioning the respective fleet resource based on the respective provisioning configuration and a set of resource provisioning rules that are accessible to an intelligence layer to ensure that provisioned resources comply with the provisioning rules.
  • the method further includes deploying the robotic fleet to perform the job.
  • the respective status of the resource includes a general availability of the resource. In some embodiments, determining the robotic fleet configuration data structure is further based on an environment of the job. In some embodiments, determining the robotic fleet configuration data structure is further based on a budget for the job. In some embodiments, determining the robotic fleet configuration data structure is further based on a timeline for completing the job. In some embodiments, the fleet resource inventory includes one or more types of robots and determining the robotic fleet configuration data structure is further based on an available inventory of the one or more types of robots. In some embodiments, determining a provisioning configuration for each respective fleet resource is further based on an environment of the job.
  • determining a provisioning configuration for each respective fleet resource is further based on a budget for the job. In some embodiments, determining a provisioning configuration for each respective assigned fleet resource is further based on a timeline for completing the job. In some embodiments, the fleet resource inventory includes computing resources selected from a list of computing resources comprising on-robot computing resources, robot operating unit-local fleet-controlled computing resources, cloud based computing resources, computing modules, or computing chips.
  • provisioning the respective fleet resource includes provisioning one or more of a software robot module or a hardware robot module.
  • the hardware robot module is an interchangeable module.
  • the fleet resource inventory includes a plurality of digital resources.
  • provisioning a respective one of the plurality of digital resources includes one or more of software update pushing, resource access credentialing, or fleet resource data storage configuration, allocation, or utilization.
  • provisioning a respective fleet resource includes provisioning a consumable resource sourced from at least one of a specialized supply chain, a job requestor resource supply, a fleet-specific stockpile, a job-specific stockpile, or a fleet team-specific stockpile.
  • provisioning the respective fleet resource is based on one or more characteristics of a target operating environment.
  • a target operating environment is one or more of land-based, sea-based, submerged, in-flight, subterranean, and below-freezing ambient temperature.
  • provisioning the respective fleet resource includes 3D printing the respective resource for provisioning.
  • provisioning the respective fleet resource is based on terms of a smart contract that constrains provisioning of fleet resources.
  • the fleet resource inventory includes platform resources and provisioning the respective fleet resource includes provisioning at least one platform resource selected from a list of platform resources including computing resources, a fleet configuration system, a platform intelligence layer, a platform data processing system, and a fleet security system.
  • determining a robotic fleet configuration data structure is further based on a negotiated charge for provisioning a platform resource.
  • determining a robotic fleet configuration data structure includes a negotiation workflow for acceptance of the job request.
  • provisioning the respective fleet resource includes provisioning one or more fleet resources identified in a job execution plan. In some embodiments, provisioning the respective fleet resource includes provisioning one or more of appendages, sensor sets, chipsets, and motive adaptors to a robot based on at least one task in a set of target tasks for the robot that are identified in a job execution plan. In some embodiments, provisioning the respective fleet resource includes analyzing a job execution plan that defines resources for a fleet of robots for performing at least one task. In some embodiments, the method further includes executing cooperatively with at least one of a fleet configuration system, a fleet resource scheduling system, a fleet security system, and a fleet utilization system.
  • a robotic fleet platform for configuring robot fleets with additive manufacturing capabilities.
  • the platform includes a computer-readable storage system that stores: a fleet resources data store that maintains a fleet resource inventory that indicates a plurality of additive manufacturing systems that can be provisioned with a set of fleet resources, and for each respective additive manufacturing system, a set of 3D printing requirements, printing instructions that define configuring an on-demand production system for 3D printing, and a status of the additive manufacturing system; and a set of additive manufacturing system provisioning rules that are accessible to an intelligence layer to ensure that provisioned additive manufacturing systems comply with the provisioning rules.
  • the platform further includes a set of one or more processors that execute a set of computer-readable instructions.
  • the set of one or more processors collectively receive a request for a robotic fleet to perform a job.
  • the set of one or more processors collectively determine a job definition data structure based on the request, the job definition data structure defining a set of tasks that are to be performed in performance of the job.
  • the set of one or more processors collectively determine a robotic fleet configuration data structure corresponding to the job based on the set of tasks and the fleet resource inventory, wherein the robotic fleet configuration data structure assigns one or more additive manufacturing systems selected from the fleet resource inventory to one or more of the set of tasks defined in the job definition data structure.
  • the set of one or more processors collectively determine a respective provisioning configuration for each respective additive manufacturing system based on the respective task to which the additive manufacturing system is assigned, the set of 3D printing requirements, the printing instructions, and the respective status of the additive manufacturing system.
  • the set of one or more processors collectively provision the respective additive manufacturing system based on the respective provisioning configuration and the provisioning rules.
  • the set of one or more processors collectively deploy the robotic fleet based on the robotic fleet configuration data structure to perform the job.
  • provisioning the respective additive manufacturing system includes to provision a 3D printing capable robot.
  • the respective provisioning configuration for each respective additive manufacturing system includes a set of 3D printing instructions for at least one of a job-specific end effector or an adaptor based on a context of the task to which the additive manufacturing system is assigned.
  • the robotic fleet configuration data structure assigns control of at least one transportable 3D printing additive manufacturing system to at least one robot operating unit.
  • determining the robotic fleet configuration data structure is further based on availability and job site locality of 3D printing resources. In some of these embodiments, at least one of the availability or job site locality of the 3D printing resource is identified by a logistics system of the platform. In some embodiments, determining the robotic fleet configuration data structure includes assignment of at least one additive manufacturing system indicated in the fleet resource inventory based on proximity to a job site for the requested job.
  • determining a respective provisioning configuration for each respective additive manufacturing system includes use of an artificial intelligence system to automate design for 3D printing of one or more robotic accessories.
  • the artificial intelligence system automates design for 3D printing based on contextual task recognition. Additionally or alternatively, the artificial intelligence system automates design for 3D printing based on automated shape recognition capabilities. Additionally or alternatively, provisioning the respective additive manufacturing system includes provisioning a 3D printing control capability to produce an end effector based on a visual and sensed analysis of an object for manipulation of which the end effector is to be 3D printed.
  • deploying the robotic fleet includes use of a fleet configuration scheduling resource of the platform for allocation of the respective additive manufacturing system to perform the job.
  • deploying the robotic fleet includes deploying a 3D printing robot to a smart container for remote, on-demand additive manufacturing.
  • determining a respective provisioning configuration for each respective additive manufacturing system is further based on one or more keywords of the job definition data structure that are indicative of an operating condition for the respective additive manufacturing system.
  • deploying the robotic fleet includes deploying a set of autonomous 3D printing additive manufacturing system to points of service work indicated in the job definition data structure.
  • determining a respective provisioning configuration for each respective additive manufacturing system includes configuring a 3D printing system to receive a tokenized instance of a set of 3D printing instructions associated with a corresponding token on a distributed ledger.
  • deploying the robotic fleet includes deploying the respective additive manufacturing system as a 3D printing resource shared among a plurality of tasks.
  • a method of configuring robot fleets with additive manufacturing capabilities includes receiving a request for a robotic fleet to perform a job.
  • the method further includes determining a job definition data structure based on the request, the job definition data structure defining a set of tasks that are to be performed in performance of the job.
  • the method further includes determining a robotic fleet configuration data structure corresponding to the job based on the set of tasks and a fleet resource inventory that indicates a plurality of additive manufacturing systems that can be provisioned with a set of fleet resources, and for each respective additive manufacturing system, a set of 3D printing requirements, printing instructions that define configuring an on-demand production system for 3D printing, and a status of the additive manufacturing system, wherein the robotic fleet configuration data structure assigns one or more additive manufacturing systems selected from the fleet resource inventory to one or more of the set of tasks defined in the job definition data structure.
  • the method further includes determining a respective provisioning configuration for each respective additive manufacturing system based on the respective task to which the additive manufacturing system is assigned, the set of 3D printing requirements, the printing instructions, and the respective status of the additive manufacturing system.
  • the method further includes provisioning the respective additive manufacturing system based on the respective provisioning configuration and a set of additive manufacturing system provisioning rules that are accessible to an intelligence layer to ensure that provisioned additive manufacturing systems comply with the provisioning rules.
  • the method further includes deploying the robotic fleet based on the robotic fleet configuration data structure to perform the job.
  • provisioning the respective additive manufacturing system includes provisioning a 3D printing capable robot.
  • the respective provisioning configuration for each respective additive manufacturing system includes a set of 3D printing instructions for at least one of a job-specific end effector or an adaptor based on a context of the task to which the additive manufacturing system is assigned.
  • the robotic fleet configuration data structure assigns control of at least one transportable 3D printing additive manufacturing system to at least one robot operating unit.
  • determining the robotic fleet configuration data structure is further based on availability and job site locality of 3D printing resources. In some of these embodiments, at least one of the availability or job site locality of the 3D printing resource is identified by a logistics system of the platform. In some embodiments, determining the robotic fleet configuration data structure includes assignment of at least one additive manufacturing system indicated in the fleet resource inventory based on proximity to a job site for the requested job.
  • determining a respective provisioning configuration for each respective additive manufacturing system includes use of an artificial intelligence system to automate design for 3D printing of one or more robotic accessories.
  • the artificial intelligence system automates design for 3D printing based on contextual task recognition. Additionally or alternatively, the artificial intelligence system automates design for 3D printing based on automated shape recognition capabilities. Additionally or alternatively, provisioning the respective additive manufacturing system includes provisioning a 3D printing control capability to produce an end effector based on a visual and sensed analysis of an object for manipulation of which the end effector is to be 3D printed.
  • deploying the robotic fleet includes use of a fleet configuration scheduling resource of the platform for allocation of the respective additive manufacturing system to perform the job.
  • deploying the robotic fleet includes deploying a 3D printing robot to a smart container for remote, on-demand additive manufacturing.
  • determining a respective provisioning configuration for each respective additive manufacturing system is further based on one or more keywords of the job definition data structure that are indicative of an operating condition for the respective additive manufacturing system.
  • deploying the robotic fleet includes deploying a set of autonomous 3D printing additive manufacturing system to points of service work indicated in the job definition data structure.
  • determining a respective provisioning configuration for each respective additive manufacturing system includes configuring a 3D printing system to receive a tokenized instance of a set of 3D printing instructions associated with a corresponding token on a distributed ledger.
  • deploying the robotic fleet includes deploying the respective additive manufacturing system as a 3D printing resource shared among a plurality of tasks.
  • provisioning the respective additive manufacturing system includes interacting with at least one of a fleet operating system, a fleet configuration system, a fleet resource scheduling system, and a fleet utilization system. In some of these embodiments, interacting includes ensuring that the provisioning rules are followed. In some embodiments, the provisioning rules are defined in a governance standards library and an intelligence service ensures that the provisioned resources comply with the provisioning rules.
  • a dynamic vision system for robot fleet management includes an optical assembly including a lens containing a liquid, wherein the lens is deformable to generate variable focus for the lens, and wherein the optical assembly is configured to capture optical data.
  • the system further includes a robot fleet management platform having a control system configured to adjust one or more optical parameters, wherein the one or more optical parameters modify the variable focus of the lens while the optical assembly captures current optical data relating to a robotic fleet.
  • the system further includes a processing system configured to train a machine learning model to recognize an object relating to the robotic fleet using training data generated from the optical data captured by the optical assembly, wherein the optical data includes the current optical data relating to the robotic fleet.
  • the optical data captured by the optical assembly includes optical data that is out-of-focus with respect to an object being optically captured by the optical assembly.
  • the recognition of an object relating to the robotic fleet is compared to a stored fleet resource configuration comprised of a plurality of objects.
  • the comparison of the recognized object to the stored fleet resource configuration is quantified as a numeric score, wherein the numeric score represents the degree of match between the recognized object and that object type's position in the stored fleet resource configuration.
  • the numeric score is compared against a stored numeric score threshold, wherein the numeric score threshold represents a minimum degree of match between the recognized object and that object type's position in the stored fleet resource configuration.
  • the robotic fleet management platform generates an alert upon detection of the numeric score not meeting or exceeding the stored numeric score threshold.
  • the robotic fleet management platform pauses robotic activity of at least one robotic apparatus upon detection of the numeric score not meeting or exceeding the stored numeric score threshold.
  • the optical parameters deform the lens from an original state by applying an electrical current to the lens.
  • the optical parameters adjust the variable focus of the lens at a predetermined frequency.
  • the optical parameters adjust the variable focus of the lens from a first focal state to a second focal state different than the first focal state, wherein the training data includes optical data captured in the first focal state, and wherein the training data incorporates feedback data such that the training data includes optical data captured in the first focal state and the second focal state.
  • an information technology system for a distributed manufacturing network includes an additive manufacturing management platform configured to manage process workflows for a set of distributed manufacturing network entities associated with the distributed manufacturing network, wherein one of the process workflows includes a design stage, a modeling stage, a printing stage, and a supply chain stage, wherein the modeling stage includes a digital twin modeling system defined at least in part by at least one of a product instruction or the control tower instruction to encode a set of digital twins representing a product for use by the additive manufacturing management platform.
  • the system further includes an artificial intelligence system executable by a data processing system in communication with the additive manufacturing management platform, wherein the artificial intelligence system is trained to generate process parameters for the process workflows managed by the additive manufacturing management platform using data collected from the distributed manufacturing network entities.
  • the system further includes a control system configured to adjust the process parameters during an additive manufacturing process performed by at least one of the distributed manufacturing network entities.
  • the set of distributed manufacturing network entities includes: a first additive manufacturing unit configured to perform a first additive manufacturing process; and a second additive manufacturing unit configured to perform a second additive manufacturing process, wherein the first additive manufacturing process is different than the second additive manufacturing process.
  • the training data includes: (i) outcomes; (ii) data collected; and (iii) prior/historical process parameters.
  • the additive manufacturing process is a hybrid task requiring at least two different types of additive manufacturing units.
  • the additive manufacturing management platform is cloud-based.
  • the artificial intelligence system is distributed across more than one distributed manufacturing network entity.
  • the digital twins representing a product are used by the additive manufacturing management platform to manufacture a physical replica of the digitally represented product.
  • the artificial intelligence system includes an adaptive intelligence system in communication with a plurality of sensors and configured to receive current sensor data from the plurality of sensors for use in encoding the set of digital twins.
  • the artificial intelligence system is distributed across more than one distributed manufacturing network entities from the set of distributed manufacturing network entities.
  • the representation of the product is a simulated future condition state of the product.
  • An autonomous futures contract orchestration platform includes a set of one or more processors programmed with a set of non-transitory computer-readable instructions to collectively execute receiving, from a data source, an indication associated with a product that relates to an entity that at least one of purchases or sells the product. They further execute predicting a baseline cost of at least one of purchasing or selling the product at a future point in time based on the indication. They further execute retrieving a futures cost, at a current point in time, of a futures contract for an obligation to the at least one of purchasing or selling the product for at least one of delivery or performance of the product at the future point in time. They further execute executing a smart contract for the futures contract based on the baseline cost and the futures cost. They further execute orchestrating the at least one of delivery or performance of the product at the future point in time.
  • the autonomous futures contract orchestration platform includes a risk data structure indicating an amount of risk the entity is willing to accept with respect to the baseline cost and the futures cost.
  • the computer-readable instructions collectively execute executing the smart contract based on the risk data structure to at least one of manage or mitigate risk.
  • the autonomous futures contract orchestration platform includes a robotic process automation system for demand-side planning to orchestrate the smart futures contract.
  • the autonomous futures contract orchestration platform includes a robotic agent configured to derisk with respect to the futures contract and the smart contract.
  • the autonomous futures contract orchestration platform includes a system for performing circular economy optimization based on futures pricing of goods.
  • the computer-readable instructions collectively execute initializing a robotic process automation system trained to execute the smart contract and executing the smart contract using the robotic process automation system.
  • the indication is of at least one of an event occurrence, a physical condition of an item, or a potential demand increase.
  • An autonomous futures contract orchestration platform includes a set of one or more processors programmed with a set of non-transitory computer-readable instructions to collectively execute retrieving a futures cost, at a current point in time, of a futures contract for an obligation to at least one of purchase or sell a product for at least one of delivery or performance of the product to an entity at a future point in time. They further execute predicting a baseline cost to the entity of the at least one of purchasing or selling the product at the future point in time. They further execute executing a smart contract for the futures contract based on the baseline cost and the futures cost. They further execute orchestrating the at least one of delivery or performance of the product to the entity at the future point in time.
  • a computerized method for autonomous future contract orchestration includes receiving, from a data source, an indication associated with a product that relates to an entity that at least one of purchases or sells the product.
  • the method includes predicting a baseline cost of at least one of purchasing or selling the product at a future point in time based on the indication.
  • the method includes retrieving a futures cost, at a current point in time, of a futures contract for an obligation to the at least one of purchasing or selling the product for at least one of delivery or performance of the product at the future point in time.
  • the method includes executing a smart contract for the futures contract based on the baseline cost and the futures cost.
  • the method includes orchestrating the at least one of delivery or performance of the product at the future point in time.
  • the computerized method includes retrieving a risk data structure indicating an amount of risk the entity is willing to accept with respect to the baseline cost and the futures cost and executing the smart contract based on the risk data structure to at least one of manage or mitigate risk.
  • the computerized method includes demand-side planning using a robotic process automation system and orchestrating the smart futures contract based on the demand-side planning
  • the computerized method includes derisking with respect to the futures contract and the smart contract using a robotic agent.
  • the computerized method includes executing a system for performing circular economy optimization based on futures pricing of goods.
  • the computerized method includes initializing a robotic process automation system trained to execute the smart contract and executing the smart contract using the robotic process automation system.
  • retrieving the indication includes retrieving at least one of an event occurrence, a physical condition of an item, or a potential demand increase.
  • An autonomous futures contract orchestration platform includes a set of one or more processors programmed with a set of non-transitory computer-readable instructions to collectively execute receiving, from a data source, an indication associated with a product that relates to an entity that at least one of purchases or sells the product. They further execute predicting a baseline cost of at least one of purchasing or selling the product at a future point in time based on the indication. They further execute retrieving a futures cost, at a current point in time, of a futures contract for the product. They further execute generating a risk threshold based on a predefined risk tolerance of the entity indicating a difference between the baseline cost and the futures cost. They further execute executing a smart contract for the futures contract based on the baseline cost, the futures cost, and the risk threshold.
  • the set of one or more processors are further programmed to collectively execute generating the risk threshold based on at least one of hedging for or providing improved outcomes after adverse contingencies. In other features, the set of one or more processors are further programmed to collectively execute generating the risk threshold based on at least one of: shortages in supply, supply chain disruptions, changes in demand, changes in prices of inputs, or changes in market prices as the adverse contingencies. In other features, the set of one or more processors are further programmed to collectively execute predicting the baseline cost based on providing operational efficiencies. In other features, the set of one or more processors are further programmed to collectively execute predicting the baseline cost based on at least one of insuring availability of items based on plans or insuring availability of items based on availability predictions as the operational efficiencies.
  • the set of one or more processors are further programmed to collectively execute executing the smart contract based on improving returns. In other features, the set of one or more processors are further programmed to collectively execute executing the smart contract based on obtaining inputs at more favorable prices than the baseline cost indicates. In other features, the set of one or more processors are further programmed to collectively execute executing the smart contract that interacts with futures markets associated with the futures contract. In other features, the set of one or more processors are further programmed to collectively execute executing the smart contract to engage with at least one of futures or options involving at least one of commodities, equities, currencies, or energy associated with the futures contract.
  • a computerized method for autonomous futures contract orchestration includes receiving, from a data source, an indication associated with a set of items that are provided at least one of by or within a value chain network.
  • the method includes predicting a baseline cost associated with the set of items at a future point in time based on the indication.
  • the method includes retrieving a futures cost, at a current point in time, of a futures contract associated with the set of items.
  • the method includes generating a risk threshold based on a predefined risk tolerance of an entity of the value chain network, the risk threshold indicating a difference between the baseline cost and the futures cost.
  • the method includes executing a smart contract for the futures contract based on the baseline cost, the futures cost, and the risk threshold.
  • generating the risk threshold includes generating the risk threshold based on at least one of hedging for or providing improved outcomes after adverse contingencies. In other features, generating the risk threshold includes generating the risk threshold based on at least one of: shortages in supply, supply chain disruptions, changes in demand, changes in prices of inputs, or changes in market prices as the adverse contingencies. Predicting the baseline cost includes predicting the baseline cost based on providing operational efficiencies. In other features, predicting the baseline cost includes predicting the baseline cost based on at least one of insuring availability of items based on plans or insuring availability of items based on availability predictions as the operational efficiencies.
  • executing the smart contract includes executing the smart contract based on improving returns. In other features, executing the smart contract includes executing the smart contract based on obtaining inputs at more favorable prices than the baseline cost indicates. In other features, executing the smart contract includes executing a smart contract that interacts with futures markets associated with the futures contract. In other features, executing the smart contract includes executing the smart contract to engage with at least one of futures or options involving at least one of commodities, equities, currencies, or energy associated with the futures contract.
  • a system for managing future costs associated with a product includes a future requirement system programmed to estimate an amount of resources required for manufacturing, distributing, and selling the product at a future point in time.
  • the system includes an adverse contingency system configured to identify adverse contingencies and calculate changes in costs associated with obtaining the amount of resources at the future point in time.
  • the system includes a smart contract system programmed to autonomously configure and execute a smart futures contract based on the amount of resources required and on the changes in costs to manage the future costs associated with the product.
  • the smart contract system is further programmed to execute the smart futures contract based on at least one of hedging for or providing improved outcomes after the adverse contingencies.
  • the adverse contingency system is further configured to estimate probabilities of at least one of: shortages in supply, supply chain disruptions, changes in demand, changes in prices of inputs, or changes in market prices as the adverse contingencies.
  • the adverse contingency system is further configured to estimate probabilities of at least one of: macro-economic factors, geopolitical disruptions, disruptions due to weather or climate, epidemics, pandemics, or counterparty risks as the adverse contingencies.
  • the smart contract system is programmed with a robotic agent that configures terms and conditions for the smart futures contract.
  • the smart contract system is programmed to set prices, delivery times, and delivery locations required in order to provide a pre-determined inventory of an item in response to the adverse contingencies.
  • the smart contract system is programmed to configure at least one of parts, components, fuel, or materials required to provide a pre-determined inventory of an item as a set of inputs with the robotic agent.
  • the smart contract system is programmed to train the robotic agent on a training set of interactions of a set of expert procurement professionals with a set of inputs.
  • the smart contract system is programmed to train the robotic agent with at least one of demand forecasts, inventory forecasts, demand elasticity curves, predictions of competitive behavior, supply chain predictions as demand planning inputs of the set of inputs.
  • the smart contract system is programmed to train the robotic agent with interactions within an enterprise demand planning software suite as the set of inputs.
  • the smart contract system is programmed to train the robotic agent to interact with a set of demand models that at least one of forecast demand factors, forecast supply factors, forecast pricing factors, forecast anticipated equilibria between supply and demand, generate estimates of appropriate inventory, generate recommendations for supply, or generate recommendations for distribution.
  • the smart contract system is further programmed to configure the smart contract to automatically execute to obtain commitments for supply in response to discovery of a pre-defined market condition associated with the adverse contingency.
  • a computerized method for managing future costs associated with a product includes estimating an amount of resources required for manufacturing, distributing, and selling the product at a future point in time.
  • the method includes identifying adverse contingencies.
  • the method includes calculating changes in costs associated with obtaining the amount of resources at the future point in time.
  • the method includes autonomously configuring and executing a smart futures contract based on the amount of resources required and on the changes in costs to manage the future costs associated with the product.
  • executing the smart contract includes executing the smart futures contract based on at least one of hedging for or providing improved outcomes after the adverse contingencies.
  • the computerized method includes estimating probabilities of at least one of: shortages in supply, supply chain disruptions, changes in demand, changes in prices of inputs, or changes in market prices as the adverse contingencies.
  • the computerized method includes estimating probabilities of at least one of: macro-economic factors, geopolitical disruptions, disruptions due to weather or climate, epidemics, pandemics, or counterparty risks as the adverse contingencies.
  • the computerized method includes configuring terms and conditions for the smart futures contract with a robotic agent.
  • the computerized method includes configuring at least one of parts, components, fuel, or materials required to provide a pre-determined inventory of an item as a set of inputs with the robotic agent.
  • the computerized method includes training the robotic agent on a training set of interactions of a set of expert procurement professionals with a set of inputs.
  • the computerized method includes training the robotic agent to interact with a set of demand models that at least one of forecast demand factors, forecast supply factors, forecast pricing factors, forecast anticipated equilibria between supply and demand, generate estimates of appropriate inventory, generate recommendations for supply, or generate recommendations for distribution.
  • a raw material system includes a product manufacturing demand estimation system programmed to calculate an expected demand for a product at a future point in time.
  • the system includes an environment detection system configured to identify at least one of an environmental condition or an environmental event.
  • the system includes a raw material production system programmed to estimate a raw material availability at the future point in time based on the expected demand and the at least one of the environmental condition or the environmental event.
  • the system includes a raw material requirement system programmed to calculate a required raw material amount to manufacture the product at the future point in time based on the expected demand and on the at least one of the environmental condition or the environmental event.
  • the system includes a raw material procurement system programmed to autonomously configure a futures contract for procurement of at least a portion of the required raw material amount in response to the required raw material amount calculation exceeding the raw material availability estimation.
  • the raw material production system is further programmed to estimate a probability that the raw material availability will decrease based on a rise in demand outpacing a production increase.
  • the raw material requirement system is further programmed with a demand aggregation service configured to monitor a demand response across a plurality of systems.
  • the demand aggregation service is further configured to monitor the demand response as changes in at least one of supply, price changes, customization, pricing, or advertising.
  • the raw material system includes a risk tolerance system configured to retrieve a pre-determined risk tolerance of an entity that procures the raw material.
  • the raw material procurement system is further programmed to autonomously configure the futures contract based at least in part on the pre-determined risk tolerance.
  • the raw material procurement system is further configured to execute a smart contract for the futures contract.
  • the raw material system includes a digital wallet coupled with the raw material procurement system to enable payments associated with the smart contract.
  • the raw material procurement system is further configured with a robotic process automation (RPA) service to facilitate automation of producing and validating the smart contract.
  • RPA robotic process automation
  • the RPA service is configured to automate processes based on observations of human interactions with hardware elements and with software elements.
  • the raw material procurement system is further configured to configure the smart contract to interact with a distribution system to secure at least one of delivery, storage, or handling of the raw materials through the distribution system.
  • the raw material procurement system is further configured to configured the smart contract to interact with a logistics reservations futures system to secure future logistics services.
  • the raw material procurement system is further configured to configure the smart contract to secure at least one of port docking reservations, shipping container reservations, trucking reservations, warehouse space rental, or canal passage rental as the future logistics services.
  • the raw materials include at least one of copper, steel, iron, or lithium.
  • a computerized method for raw material procurement includes calculating an expected demand for a product at a future point in time.
  • the method includes identifying at least one of an environmental condition or an environmental event.
  • the method includes estimating a raw material availability of a raw material at the future point in time based on the expected demand and the at least one of the environmental condition or the environmental event.
  • the method includes calculating a required raw material amount of the raw material to manufacture the product at the future point in time based on the expected demand and on the at least one of the environmental condition or the environmental event.
  • the method includes autonomously configuring a futures contract for procurement of at least a portion of the required raw material amount in response to the required raw material amount calculation exceeding the raw material availability estimation.
  • the computerized method includes estimating a probability that the raw material availability will decrease based on a rise in demand outpacing a production increase.
  • the computerized method includes monitoring a demand response across a plurality of systems.
  • monitoring the demand response further includes to monitoring the demand response as changes in at least one of supply, price changes, customization, pricing, or advertising.
  • the computerized method includes retrieving a pre-determined risk tolerance of an entity that procures the raw material. Autonomously configuring the futures contract is based at least in part on the pre-determined risk tolerance.
  • the computerized method includes executing a smart contract for the futures contract.
  • the computerized method includes engaging a digital wallet to enable payments associated with the smart contract.
  • a system for product replacement includes a product logistics system for a product in a product condition.
  • the system includes an exposure data collection system configured to collect exposure data indicating at least one of an event or an environmental condition that may impact the product condition of the product.
  • the system includes a replacement determination system programmed to calculate a probability for the need to replace the product based on the at least one of the event or the environmental condition.
  • the system includes a replacement procurement system programmed to autonomously configure an option-type futures contract for replacement of the product based on the probability for the need to replace the product.
  • the system includes a smart contract system programmed to autonomously configure a smart contract to secure replacement of the product based on the option-type futures contract.
  • the smart contract system configures the smart contract to have a duration of option based on estimating a time until an actual determination of the need to replace the product based on physical examination may be performed.
  • the smart contract system configures the smart contract to have the duration of options further based on a probability of catastrophic loss indicated by the probability for the need to replace the product.
  • the system includes a replacement alternatives system programmed to configure an alternative smart contract that offers alternatives to replacement of the product to at least one of a purchaser of, an owner of, or an insurer with a security interest in the product.
  • the replacement alternatives system is programmed to configure the alternative smart contract that offers a refund of a purchase price of the product. In other features, the replacement alternatives system is programmed to configure the alternative smart contract that offers alternative goods or services. In other features, the replacement alternatives system is programmed to configure the alternative smart contract that offers incentives to accept a delayed delivery of the product.
  • the system includes a future price renegotiation system programmed to renegotiate a set of future prices based on a current market state and on the exposure data.
  • the future price renegotiation system is further programmed to renegotiate the set of future prices in response to the exposure data indicating a likelihood of widespread supply chain disruptions for goods or services associated with the product.
  • the system includes an artificial intelligence (AI) system trained on historical data sets to predict the probability that the product will need to be replaced based on the exposure data.
  • the AI system is trained to predict the impact of the need for replacement.
  • the AI system is trained to predict the impact of the need based on at least one of an impact of delays or reduced supply on pricing.
  • the exposure data collection system is further configured to collect the exposure data from sensors disposed on at least one of the product, a package for the product, a transport vehicle in which the product is located, or proximal infrastructure.
  • a computerized method for product replacement of a product in a product condition includes collecting exposure data indicating at least one of an event or an environmental condition that may impact the product condition of the product.
  • the method includes calculating a probability for the need to replace the product based on the at least one of the event or the environmental condition.
  • the method includes autonomously configuring an option-type futures contract for replacement of the product based on the probability for the need to replace the product.
  • the computerized method includes autonomously configuring a smart contract to secure replacement of the product based on the option-type futures contract.
  • the computerized method includes estimating a time until an actual determination of the need to replace the product will be performed.
  • Configuring the smart contract includes configuring the smart contract to have a duration of option based on the time until the actual determination will be performed.
  • configuring the smart contract includes configuring the smart contract to have the duration of options further based on a probability of catastrophic loss indicated by the probability for the need to replace the product.
  • the computerized method includes configuring an alternative smart contract that offers alternatives to replacement of the product to at least one of a purchaser of, an owner of, or an insurer with a security interest in the product.
  • configuring the alternative smart contract includes configuring the alternative smart contract that offers a refund of a purchase price of the product.
  • FIG. 1 is a block diagram showing prior art relationships of various entities and facilities in a supply chain.
  • FIG. 2 is a block diagram showing components and interrelationships of systems and processes of a value chain network in accordance with the present disclosure.
  • FIG. 3 is another block diagram showing components and interrelationships of systems and processes of a value chain network in accordance with the present disclosure.
  • FIG. 4 is a block diagram showing components and interrelationships of systems and processes of a digital products network of FIGS. 2 and 3 in accordance with the present disclosure.
  • FIG. 5 is a block diagram showing components and interrelationships of systems and processes of a value chain network technology stack in accordance with the present disclosure.
  • FIG. 6 is a block diagram showing a platform and relationships for orchestrating controls of various entities in a value chain network in accordance with the present disclosure.
  • FIG. 7 is a block diagram showing components and relationships in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 8 is a block diagram showing components and relationships of value chain entities managed by embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 9 is a block diagram showing network relationships of entities in a value chain network in accordance with the present disclosure.
  • FIG. 10 is a block diagram showing a set of applications supported by unified data handling layers in a value chain network management platform in accordance with the present disclosure.
  • FIG. 11 is a block diagram showing components and relationships in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 12 is a block diagram showing components and relationships of a data storage layer in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 13 is a block diagram showing components and relationships of an adaptive intelligent systems layer in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 14 is a block diagram that depicts providing adaptive intelligence systems for coordinated intelligence for sets of demand and supply applications for a category of goods in accordance with the present disclosure.
  • FIG. 15 is a block diagram that depicts providing hybrid adaptive intelligence systems for coordinated intelligence for sets of demand and supply applications or a category of goods in accordance with the present disclosure.
  • FIG. 16 is a block diagram that depicts providing adaptive intelligence systems for predictive intelligence for sets of demand and supply applications for a category of goods in accordance with the present disclosure.
  • FIG. 17 is a block diagram that depicts providing adaptive intelligence systems for classification intelligence for sets of demand and supply applications for a category of goods in accordance with the present disclosure.
  • FIG. 18 is a block diagram that depicts providing adaptive intelligence systems to produce automated control signals for sets of demand and supply applications for a category of goods in accordance with the present disclosure.
  • FIG. 19 is a block diagram that depicts training artificial intelligence/machine learning systems to produce information routing recommendations for a selected value chain network in accordance with the present disclosure.
  • FIG. 20 is a block diagram that depicts a semi-sentient problem recognition system for recognition of pain points/problem states in a value chain network in accordance with the present disclosure.
  • FIG. 21 is a block diagram that depicts a set of artificial intelligence systems operating on value chain information to enable automated coordination of value chain activities for an enterprise in accordance with the present disclosure.
  • FIG. 22 is a block diagram showing components and relationships involved in integrating a set of digital twins in an embodiment of a value chain network management platform in accordance with the present disclosure.
  • FIG. 23 is a block diagram showing a set of digital twins involved in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 24 is a block diagram showing components and relationships of entity discovery and management systems in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 25 is a block diagram showing components and relationships of a robotic process automation system in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 26 is a block diagram showing components and relationships of a set of opportunity miners in an embodiment of a value chain network management platform in accordance with the present disclosure.
  • FIG. 27 is a block diagram showing components and relationships of a set of edge intelligence systems in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 28 is a block diagram showing components and relationships in an embodiment of a value chain network management platform in accordance with the present disclosure.
  • FIG. 29 is a block diagram showing additional details of components and relationships in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 30 is a block diagram showing components and relationships in an embodiment of a value chain network management platform that enables centralized orchestration of value chain network entities in accordance with the present disclosure.
  • FIG. 31 is a block diagram showing components and relationships of a unified database in an embodiment of a value chain network management platform in accordance with the present disclosure.
  • FIG. 32 is a block diagram showing components and relationships of a set of unified data collection systems in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 33 is a block diagram showing components and relationships of a set of Internet of Things monitoring systems in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 34 is a block diagram showing components and relationships of a machine vision system and a digital twin in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 35 is a block diagram showing components and relationships of a set of adaptive edge intelligence systems in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 36 is a block diagram showing additional details of components and relationships of a set of adaptive edge intelligence systems in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 37 is a block diagram showing components and relationships of a set of unified adaptive intelligence systems in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 38 is a schematic of a system configured to train an artificial system that is leveraged by a value chain system using real world outcome data and a digital twin system according to some embodiments of the present disclosure.
  • FIG. 39 is a schematic of a system configured to train an artificial system that is leveraged by a container fleet management system using real world outcome data and a digital twin system according to some embodiments of the present disclosure.
  • FIG. 40 is a schematic of a system configured to train an artificial system that is leveraged by a logistics design system using real world outcome data and a digital twin system according to some embodiments of the present disclosure.
  • FIG. 41 is a schematic of a system configured to train an artificial system that is leveraged by a packaging design system using real world outcome data and a digital twin system according to some embodiments of the present disclosure.
  • FIG. 42 is a schematic of a system configured to train an artificial system that is leveraged by a waste mitigation system using real world outcome data and a digital twin system according to some embodiments of the present disclosure.
  • FIG. 43 is a schematic illustrating an example of a portion of an information technology system for value chain artificial intelligence leveraging digital twins according to some embodiments of the present disclosure.
  • FIG. 44 is a block diagram showing components and relationships of a set of intelligent project management facilities in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 45 is a block diagram showing components and relationships of an intelligent task recommendation system in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 46 is a block diagram showing components and relationships of a routing system among nodes of a value chain network in embodiments of a value chain network management platform in accordance with the present disclosure.
  • FIG. 47 is a block diagram showing components and relationships of a dashboard for managing a set of digital twins in embodiments of a value chain network management platform.
  • FIG. 48 is a block diagram showing components and relationships in embodiments of a value chain network management platform that uses a microservices architecture.
  • FIG. 49 is a block diagram showing components and relationships of an Internet of Things data collection architecture and sensor recommendation system in embodiments of a value chain network management platform.
  • FIG. 50 is a block diagram showing components and relationships of a social data collection architecture in embodiments of a value chain network management platform.
  • FIG. 51 is a block diagram showing components and relationships of a crowdsourcing data collection architecture in embodiments of a value chain network management platform.
  • FIG. 52 is a diagrammatic view that depicts embodiments of a set of value chain network digital twins representing virtual models of a set of value chain network entities in accordance with the present disclosure.
  • FIG. 53 is a diagrammatic view that depicts embodiments of a warehouse digital twin kit system in accordance with the present disclosure.
  • FIG. 54 is a diagrammatic view that depicts embodiments of a stress test performed on a value chain network in accordance with the present disclosure.
  • FIG. 55 is a diagrammatic view that depicts embodiments of methods used by a machine for detecting faults and predicting any future failures of the machine in accordance with the present disclosure.
  • FIG. 56 is a diagrammatic view that depicts embodiments of deployment of machine twins to perform predictive maintenance on a set of machines in accordance with the present disclosure.
  • FIG. 57 is a schematic illustrating an example of a portion of a system for value chain customer digital twins and customer profile digital twins according to some embodiments of the present disclosure.
  • FIG. 58 is a schematic illustrating an example of an advertising application that interfaces with the adaptive intelligent systems layer in accordance with the present disclosure.
  • FIG. 59 is a schematic illustrating an example of an e-commerce application integrated with the adaptive intelligent systems layer in accordance with the present disclosure.
  • FIG. 60 is a schematic illustrating an example of a demand management application integrated with the adaptive intelligent systems layer in accordance with the present disclosure.
  • FIG. 61 is a schematic illustrating an example of a portion of a system for value chain smart supply component digital twins according to some embodiments of the present disclosure.
  • FIG. 62 is a schematic illustrating an example of a risk management application that interfaces with the adaptive intelligent systems layer in accordance with the present disclosure.
  • FIG. 63 is a diagrammatic view of maritime assets associated with a value chain network management platform including components of a port infrastructure in accordance with the present disclosure.
  • FIGS. 64 and 65 are diagrammatic views of maritime assets associated with a value chain network management platform including components of a ship in accordance with the present disclosure.
  • FIG. 66 is a diagrammatic view of maritime assets associated with a value chain network management platform including components of a barge in accordance with the present disclosure.
  • FIG. 67 is a diagrammatic view of maritime assets associated with a value chain network management platform including those involved in maritime events, legal proceedings and making use of geofenced parameters in accordance with the present disclosure.
  • FIG. 68 is a schematic illustrating an example environment of the enterprise and executive control tower and management platform, including data sources in communication therewith, according to some embodiments of the present disclosure.
  • FIG. 69 is a schematic illustrating an example set of components of the enterprise control tower and management platform according to some embodiments of the present disclosure.
  • FIG. 70 is a schematic illustrating and example of an enterprise data model according to some embodiments of the disclosure.
  • FIG. 71 is a schematic illustrating examples of different types of enterprise digital twins, including executive digital twins, in relation to the data layer, processing layer, and application layer of the enterprise digital twin framework according to some embodiments of the present disclosure.
  • FIG. 72 is a schematic illustrating an example implementation of the enterprise and executive control tower and management platform according to some embodiments of the present disclosure.
  • FIG. 73 is a flow chart illustrating an example set of operations for configuring and serving an enterprise digital twin.
  • FIG. 74 illustrates an example set of operations of a method for configuring an organizational digital twin.
  • FIG. 75 illustrates an example set of operations of a method for generating an executive digital twin.
  • FIGS. 76 - 103 are schematic diagrams of embodiments of neural net systems that may connect to, be integrated in, and be accessible by the platform for enabling intelligent transactions including ones involving expert systems, self-organization, machine learning, artificial intelligence and including neural net systems trained for pattern recognition, for classification of one or more parameters, characteristics, or phenomena, for support of autonomous control, and other purposes in accordance with embodiments of the present disclosure.
  • FIG. 104 is a schematic illustrating an example intelligence services system according to some embodiments of the present disclosure.
  • FIG. 105 is a schematic illustrating an example neural network with multiple layers according to some embodiments of the present disclosure.
  • FIG. 106 is a schematic illustrating an example convolutional neural network (CNN) according to some embodiments of the present disclosure.
  • FIG. 107 is a schematic illustrating an example neural network for implementing natural language processing according to some embodiments of the present disclosure.
  • FIG. 108 is a schematic illustrating an example reinforcement learning-based approach for executing one or more tasks by a mobile system according to some embodiments of the present disclosure.
  • FIG. 109 is a schematic illustrating an example physical orientation determination chip according to some embodiments of the present disclosure.
  • FIG. 110 is a schematic illustrating an example network enhancement chip according to some embodiments of the present disclosure.
  • FIG. 111 is a schematic illustrating an example diagnostic chip according to some embodiments of the present disclosure.
  • FIG. 112 is a schematic illustrating an example governance chip according to some embodiments of the present disclosure.
  • FIG. 113 is a schematic illustrating an example prediction, classification, and recommendation chip according to some embodiments of the present disclosure.
  • FIG. 114 is a diagrammatic view illustrating an example environment of an autonomous additive manufacturing platform according to some embodiments of the present disclosure.
  • FIG. 115 is a schematic illustrating an example implementation of an autonomous additive manufacturing platform for automating and optimizing the digital production workflow for metal additive manufacturing according to some embodiments of the present disclosure.
  • FIG. 116 is a flow diagram illustrating the optimization of different parameters of an additive manufacture process according to some embodiments of the present disclosure.
  • FIG. 117 is a schematic view illustrating a system for learning on data from an autonomous additive manufacturing platform to train an artificial learning system to use digital twins for classification, predictions and decision making according to some embodiments of the present disclosure.
  • FIG. 118 is a schematic illustrating an example implementation of an autonomous additive manufacturing platform including various components along with other entities of a distributed manufacturing network according to some embodiments of the present disclosure.
  • FIG. 119 is a schematic illustrating an example implementation of an autonomous additive manufacturing platform for automating and managing manufacturing functions and sub-processes including process and material selection, hybrid part workflows, feedstock formulation, part design optimization, risk prediction and management, marketing and customer service according to some embodiments of the present disclosure.
  • FIG. 120 is a diagrammatic view of a distributed manufacturing network enabled by an autonomous additive manufacturing platform and built on a distributed ledger system according to some embodiments of the present disclosure.
  • FIG. 121 is a schematic illustrating an example implementation of a distributed manufacturing network where the digital thread data is tokenized and stored in a distributed ledger so as to ensure traceability of parts printed at one or more manufacturing nodes in the distributed manufacturing network according to some embodiments of the present disclosure.
  • FIG. 122 is a diagrammatic view illustrating an example implementation of a conventional computer vision system for creating an image of an object of interest.
  • FIG. 123 is a schematic illustrating an example implementation of a dynamic vision system for dynamically learning an object concept about an object of interest according to some embodiments of the present disclosure.
  • FIG. 124 is a schematic illustrating an example architecture of a dynamic vision system according to some embodiments of the present disclosure.
  • FIG. 125 is a flow diagram illustrating a method for object recognition by a dynamic vision system according to some embodiments of the present disclosure.
  • FIG. 126 is a schematic illustrating an example implementation of a dynamic vision system for modelling, simulating and optimizing various optical, mechanical, design and lighting parameters of the dynamic vision system according to some embodiments of the present disclosure.
  • FIG. 127 is a schematic view illustrating an example implementation of a dynamic vision system depicting detailed view of various components along with integration of the dynamic vision system with one or more third party systems according to some embodiments of the present disclosure.
  • FIG. 128 is a schematic illustrating an example environment of a fleet management platform according to some embodiments of the present disclosure.
  • FIG. 129 is a schematic illustrating example configurations of a multi-purpose robot and a special purpose robot according to some embodiments of the present disclosure.
  • FIG. 130 is a schematic illustrating an example platform-level intelligence layer of a fleet management platform according to some embodiments of the present disclosure.
  • FIG. 131 is a schematic illustrating an example configuration of an intelligence layer according to some embodiments of the present disclosure.
  • FIG. 132 is a schematic illustrating an example security framework according to some embodiments of the present disclosure.
  • FIG. 133 is a schematic illustrating an example environment of a fleet management platform according to some embodiments of the present disclosure.
  • FIG. 134 is a schematic illustrating an example data flow of a job configuration system according to some embodiments of the present disclosure.
  • FIG. 135 is a schematic illustrating an example data flow of a fleet operations system according to some embodiments of the present disclosure.
  • FIG. 136 is a schematic illustrating an example job parsing system and task definition system and an example data flow thereof according to some embodiments of the present disclosure.
  • FIG. 137 is a schematic illustrating an example fleet configuration system and an example data flow thereof according to some embodiments of the present disclosure.
  • FIG. 138 is a schematic illustrating an example workflow definition system and an example data flow thereof according to some embodiments of the present disclosure.
  • FIG. 139 is a schematic illustrating example configurations of a multi-purpose robot and components thereof according to some embodiments of the present disclosure.
  • FIG. 140 is a schematic illustrating an example architecture of the robot control system according to some embodiments of the present disclosure
  • FIG. 141 is a schematic illustrating an example architecture of the robot control system 12150 that utilizes data from multiple sensors in the vision and sensing system according to some embodiments of the present disclosure.
  • FIG. 142 is a schematic illustrating an example vision and sensing system of a robot according to some embodiments of the present disclosure.
  • FIG. 143 is a schematic illustrating an example process that is executed by a multipurpose robot to harvest crops according to some embodiments of the present disclosure.
  • FIG. 144 is a schematic illustrating an example environment of the intermodal smart container system according to some embodiments of the present disclosure.
  • FIG. 145 is a schematic illustrating example configurations of a smart container according to some embodiments of the present disclosure.
  • FIG. 146 is a schematic illustrating an intelligence service adapted to provide intelligence services to the smart intermodal container system according to some embodiments of the present disclosure.
  • FIG. 147 is a schematic illustrating a digital twin module according to some embodiments of the present disclosure according to some embodiments of the present disclosure.
  • FIG. 148 illustrates an example embodiment of a method of receiving requests to update one or more properties of digital twins of shipping entities and/or environments.
  • FIG. 149 illustrates an example embodiment of a method for updating a set of cost of downtime values in the digital twin of a smart container according to some embodiments of the present disclosure.
  • FIG. 150 is a schematic illustrating an example environment of a digital product network according to some embodiments of the present disclosure.
  • FIG. 151 is a schematic illustrating an example environment of a connected product according to some embodiments of the present disclosure.
  • FIG. 152 is a schematic illustrating an example environment of a digital product network according to some embodiments of the present disclosure.
  • FIG. 153 is a schematic illustrating an example environment of a digital product network according to some embodiments of the present disclosure.
  • FIG. 154 is a flow diagram illustrating a method of using product level data according to some embodiments of the disclosure.
  • FIG. 155 is a schematic illustrating an example environment of a digital product network according to some embodiments of the present disclosure.
  • FIG. 156 is a schematic illustrating an example of a smart futures contract system according to some embodiments of the present disclosure.
  • FIG. 157 is a schematic illustrating an example environment of an edge networking system according to some embodiments of the present disclosure.
  • FIG. 158 is a schematic illustrating an example environment of an edge networking system including a VCN bus according to some embodiments of the present disclosure.
  • FIG. 159 a schematic illustrating an example environment of an edge networking system according to some embodiments of the present disclosure including a configured device EDNW system.
  • FIG. 160 is a schematic view of an exemplary embodiment of the quantum computing service according to some embodiments of the present disclosure.
  • FIG. 161 illustrates quantum computing service request handling according to some embodiments of the present disclosure.
  • FIG. 162 is a diagrammatic view that illustrates embodiments of the biology-based value chain network system in accordance with the present disclosure.
  • FIG. 163 is a diagrammatic view of the thalamus service and how it coordinates within the modules in accordance with the present disclosure.
  • FIG. 164 is a block diagram showing an energy system that may communicate with similar systems, subsystems, components, and a value chain network management platform according to some embodiments of the present disclosure.
  • FIG. 165 is a block diagram showing a schematic of a dual-process artificial neural network system according to some embodiments of the present disclosure.
  • FIG. 166 A is a diagrammatic view that illustrates an example environment of the distributed database system in accordance with the present disclosure.
  • FIG. 166 B is a diagrammatic view that illustrates an example architecture of the distributed database system in accordance with the present disclosure.
  • FIGS. 167 A- 167 B are diagrammatic views that illustrate storage of data in the distributed database system in accordance with the present disclosure.
  • FIGS. 168 A- 168 B are diagrammatic views that illustrate systems and modules for implementing the distributed database system in accordance with the present disclosure.
  • FIG. 169 A- 169 B are process diagrams illustrating example methods for responding to queries received by the distributed database system in accordance with the present disclosure.
  • FIGS. 169 C- 169 D are process diagrams illustrating example methods for optimizing a dynamic ledger maintained by the distributed database system in accordance with the present disclosure.
  • FIGS. 170 A- 170 B are data flow diagrams that illustrate example data table creation queries being processed by the distributed database system in accordance with the present disclosure.
  • FIGS. 171 A- 171 B are data flow diagrams that illustrate example select queries being processed by the distributed database system in accordance with the present disclosure.
  • FIGS. 172 A- 172 C are data flow diagrams that illustrate the operation of example distributed join queries in the distributed database system in accordance with the present disclosure
  • value chain network refers to elements and interconnections of historically segregated demand management systems and processes and supply chain management systems and processes, enabled by the development and convergence of numerous diverse technologies.
  • a value chain control tower 260 may be connected to, in communication with, or otherwise operatively coupled with data processing facilities including, but not limited to, big data centers (e.g., big data processing 230 ) and related processing functionalities that receive data flow, data pools, data streams and/or other data configurations and transmission modalities received from, for example, digital product networks 21002 , directly from customers (e.g., direct connected customer 250 ), or some other third party 220 .
  • big data centers e.g., big data processing 230
  • related processing functionalities that receive data flow, data pools, data streams and/or other data configurations and transmission modalities received from, for example, digital product networks 21002 , directly from customers (e.g., direct connected customer 250 ), or some other third party 220 .
  • Communications related to market orchestration activities and communications 210 , analytics 232 , or some other type of input may also be utilized by the value chain control tower for demand enhancement 262 , synchronized planning 234 , intelligent procurement 238 , dynamic fulfillment 240 or some other smart operation informed by coordinated and adaptive intelligence, as described herein.
  • the value chain control tower 360 may coordinate market orchestration activities 310 including, but not limited to, demand curve management 352 , synchronization of an ecosystem 348 , intelligent procurement 344 , dynamic fulfillment 350 , value chain analytics 340 , and/or smart supply chain operations 342 .
  • the value chain control tower 360 may be connected to, in communication with, or otherwise operatively coupled with adaptive data pipelines 302 and processing facilities that may be further connected to, in communication with, or otherwise operationally coupled with external data sources 320 and a data handling stack 330 (e.g., value chain network technology) that may include intelligent, user-adaptive interfaces, adaptive intelligence and control 332 , and/or adaptive data monitoring and storage 334 , as described herein.
  • the value chain control tower 302 may also be further connected to, in communication with, or otherwise operatively coupled with additional value chain entities including, but not limited to, digital product networks 21002 , customers (e.g., directed connected customers 362 ), and/or other connected operations 364 and entities of a value chain network.
  • products may create and transmit data, such as product level data, to a communication layer within the value chain network technology stack and/or to an edge data processing facility.
  • This data may produce enhanced product level data and may be combined with third party data for further processing, modeling or other adaptive or coordinated intelligence activity, as described herein. This may include, but is not limited to, producing and/or simulating product and value chain use cases, the data for which may be utilized by products, product development processes, product design, and the like.
  • a block diagram is presented at 500 showing components and interrelationships of systems and processes of a value chain network technology stack, which may include, but is not limited to a presentation layer, an intelligence layer, and serverless functionalities such as platforms (e.g., development and hosting platforms), data facilities (e.g., relating to data with IoT and Big Data), and data aggregation facilities.
  • the presentation layer may include, but is not limited to, a user interface, and modules for investigation and discovery and tracking users' experience and engagements.
  • the intelligence layer may include, but is not limited to, a statistical and computation methods, semantic models, an analytics library, a development environment for analytics, algorithms, logic and rules, and machine learning.
  • the platforms or the value chain network technology stack may include a development environment, APIs for connectivity, cloud and/or hosting applications, and device discovery.
  • the data aggregation facilities or layer may include, but is not limited to, modules for data normalization for common transmission and heterogeneous data collection from disparate devices.
  • the data facilities or layer may include, but is not limited to, IoT and big data access, control, and collection and alternatives.
  • the value chain network technology stack may be further associated with additional data sources and/or technology enablers.
  • FIG. 6 illustrates a connected value chain network 668 in which a value chain network management platform 604 (referred to herein in some cases as a “value chain control tower,” the “VCNP,” or simply as “the system,” or “the platform”) orchestrates a variety of factors involved in planning, monitoring, controlling, and optimizing various entities and activities involved in the value chain network 668 , such as supply and production factors, demand factors, logistics and distribution factors, and the like.
  • a value chain network management platform 604 referred to herein in some cases as a “value chain control tower,” the “VCNP,” or simply as “the system,” or “the platform”
  • a unified platform 604 for monitoring and managing supply factors and demand factors as well as status information can be shared about and between various entities (e.g., including customers/consumers, suppliers, distribution such as distributors, suppliers, and production such as producers or production facilities) as demand factors are understood and accounted for, as orders are generated and fulfilled, and as products are created and moved through a supply chain.
  • the value chain network 668 may include not only an intelligent product 1510 , but all of the equipment, infrastructure, personnel and other entities involved in planning and satisfying demand for it.
  • the value chain network 668 managed by a value chain management platform 604 may include a set of value chain network entities 652 , such as, without limitation: a product 1510 , which may be an intelligent product 1510 ; a set of production facilities 674 involved in producing finished goods, components, systems, sub-systems, materials used in goods, or the like; various entities, activities and other supply factors 648 involved in supply environments 670 , such as suppliers 642 , points of origin 610 , and the like; various entities, activities and other demand factors 644 involved in demand environments 672 , such as customers 662 (including consumers, businesses, and intermediate customers such as value added resellers and distributors), retailers 664 (including online retailers, mobile retailers, conventional bricks and mortar retailers, pop-up shops and the like) and the like located and/or operating at various destinations 612 ; various distribution environments 678 and distribution facilities 658 , such as warehousing facilities 654 , fulfillment facilities 628 , and delivery systems 632 , and the like, as well
  • the value chain network management platform 604 monitors, controls, and otherwise enables management (and in some cases autonomous or semi-autonomous behavior) of a wide range of value chain network 668 processes, workflows, activities, events and applications 630 (collectively referred to in some cases simply as “applications 630 ”).
  • the value chain network management platform 604 may include a set of systems, applications, processes, modules, services, layers, devices, components, machines, products, sub-systems, interfaces, connections, and other elements working in coordination to enable intelligent management of a set of value chain entities 652 that may occur, operate, transact or the like within, or own, operate, support or enable, one or more value chain network processes, workflows, activities, events and/or applications 630 or that may otherwise be part of, integrated with, linked to, or operated on by the VCNP 604 in connection with a product 1510 (which may be any category of product, such as a finished good, software product, hardware product, component product, material, item of equipment, item of consumer packaged goods, consumer product, food product, beverage product, home product, business supply product, consumable product, pharmaceutical product, medical device product, technology product, entertainment product, or any other type of product and/or set of related services, and which may, in embodiment
  • the management platform 604 may include a set of data handling layers 608 each of which is configured to provide a set of capabilities that facilitate development and deployment of intelligence, such as for facilitating automation, machine learning, applications of artificial intelligence, intelligent transactions, state management, event management, process management, and many others, for a wide variety of value chain network applications and end uses.
  • the data handling layers 608 are configured in a topology that facilitates shared data collection and distribution across multiple applications and uses within the platform 604 by a value chain monitoring systems layer 614 .
  • the value chain monitoring systems layer 614 may include, integrate with, and/or cooperate with various data collection and management systems 640 , referred to for convenience in some cases as data collection systems 640 , for collecting and organizing data collected from or about value chain entities 652 , as well as data collected from or about the various data layers 624 or services or components thereof.
  • the data handling layers 608 are configured in a topology that facilitates shared or common data storage across multiple applications and uses of the platform 604 by a value chain network-oriented data storage systems layer 624 , referred to herein for convenience in some cases simply as a data storage layer 624 or storage layer 624 .
  • the data handling layers 608 may also include an adaptive intelligent systems layer 614 .
  • the adaptive intelligence systems layer 614 may include a set of data processing, artificial intelligence and computational systems 634 that are described in more detail elsewhere throughout this disclosure.
  • the data processing, artificial intelligence and computational systems 634 may relate to artificial intelligence (e.g., expert systems, artificial intelligence, neural, supervised, machine learning, deep learning, model-based systems, and the like).
  • the data processing, artificial intelligence and computational systems 634 may relate to various examples, in some embodiments, such as use of a recurrent network as adaptive intelligence system operating on a blockchain of transactions in a supply chain to determine a pattern, use with biological systems, opportunity mining (e.g., where artificial intelligence system may be used to monitor for new data sources as opportunities for automatically deploying intelligence), robotic process automation (e.g., automation of intelligent agents for various workflows), edge and network intelligence (e.g., implicated on monitoring systems such as adaptively using available RF spectrum, adaptively using available fixed network spectrum, adaptively storing data based on available storage conditions, adaptively sensing based on a kind of contextual sensing), and the like.
  • opportunity mining e.g., where artificial intelligence system may be used to monitor for new data sources as opportunities for automatically deploying intelligence
  • robotic process automation e.g., automation of intelligent agents for various workflows
  • edge and network intelligence e.g., implicated on monitoring systems such as adaptively using available RF spectrum, adaptively using available fixed network spectrum,
  • the data handling layers 608 may be depicted in vertical stacks or ribbons in the figures and may represent many functionalities available to the platform 604 including storage, monitoring, and processing applications and resources and combinations thereof.
  • the set of capabilities of the data handling layers 608 may include a shared microservices architecture.
  • the set of capabilities may be deployed to provide multiple distinct services or applications, which can be configured as one or more services, workflows, or combinations thereof.
  • the set of capabilities may be deployed within or be resident to certain applications or processes.
  • the set of capabilities can include one or more activities marshaled for the benefit of the platform.
  • the set of capabilities may include one or more events organized for the benefit of the platform.
  • one of the sets of capabilities of the platform may be deployed within at least a portion of a common architecture such as common architecture that supports a common data schema. In embodiments, one of the sets of capabilities of the platform may be deployed within at least a portion of a common architecture that can support a common storage. In embodiments, one of the sets of capabilities of the platform may be deployed within at least a portion of a common architecture that can support common monitoring systems. In embodiments, one or more sets of capabilities of the platform may be deployed within at least a portion of a common architecture that can support one or more common processing frameworks.
  • the set of capabilities of the data handling layers 608 can include examples where the storage functionality supports scalable processing capabilities, scalable monitoring systems, digital twin systems, payments interface systems, and the like.
  • one or more software development kits can be provided by the platform along with deployment interfaces to facilitate connections and use of the capabilities of the data handling layers 608 .
  • adaptive intelligence systems may analyze, learn, configure, and reconfigure one or more of the capabilities of the data handling layers 608 .
  • the platform 604 may, for example, include a common data storage schema serving a shipyard entity related service and a warehousing entity service. There are many other applicable examples and combinations applicable to the foregoing example including the many value chain entities disclosed herein. By way of these examples, the platform 604 may be shown to create connectivity (e.g., supply of capabilities and information) across many value chain entities.
  • the value chain network management platform 604 is illustrated in connection with a set of value chain entities 652 that may be subject to management by the platform 604 , may integrate with or into the platform 604 , and/or may supply inputs to and/or take outputs from the platform 604 , such as ones involved in or for a wide range of value chain activities (such as supply chain activities, logistics activities, demand management and planning activities, delivery activities, shipping activities, warehousing activities, distribution and fulfillment activities, inventory aggregation, storage and management activities, marketing activities, and many others, as involved in various value chain network processes, workflows, activities, events and applications 630 (collectively “applications 630 ” or simply “activities”)).
  • applications 630 or simply “activities”.
  • Connections with the value chain entities 652 may be facilitated by a set of connectivity facilities 642 and interfaces 702 , including a wide range of components and systems described throughout this disclosure and in greater detail below. This may include connectivity and interface capabilities for individual services of the platform, for the data handling layers, for the platform as a whole, and/or among value chain entities 652 , among others.
  • value chain entities 652 may include any of the wide variety of assets, systems, devices, machines, components, equipment, facilities, individuals or other entities mentioned throughout this disclosure or in the documents incorporated herein by reference, such as, without limitation: machines 724 and their components (e.g., delivery vehicles, forklifts, conveyors, loading machines, cranes, lifts, haulers, trucks, loading machines, unloading machines, packing machines, picking machines, and many others, including robotic systems, e.g., physical robots, collaborative robots (e.g., “cobots”), drones, autonomous vehicles, software bots and many others); products 650 (which may be any category of products, such as a finished goods, software products, hardware products, component products, material, items of equipment, items of consumer packaged goods, consumer products, food products, beverage products, home products, business supply products, consumable products, pharmaceutical products, medical device products, technology products, entertainment products, or any other type of products and/or set of related services); value chain processes 722 (such as shipping processes, hauling processes, maritime processes,
  • the product 1510 may be encompassed as an intelligent product 1510 or the VCNP 604 may include the intelligent product 1510 .
  • the intelligent product 1510 may be enabled with a set of capabilities such as, without limitation data processing, networking, sensing, autonomous operation, intelligent agent, natural language processing, speech recognition, voice recognition, touch interfaces, remote control, self-organization, self-healing, process automation, computation, artificial intelligence, analog or digital sensors, cameras, sound processing systems, data storage, data integration, and/or various Internet of Things capabilities, among others.
  • the intelligent product 1510 may include a form of information technology.
  • the intelligent product 1510 may have a processor, computer random access memory, and a communication module.
  • the intelligent product 1510 may be a passive intelligent product that is similar to a RFID type of data structure where the intelligent product may be pinged or read.
  • the product 1510 may be considered a value chain network entity (e.g., under control of platform) and may be rendered intelligent by surrounding infrastructure and adding an RFID such that data may be read from the intelligent product 1510 .
  • the intelligent product 1510 may fit in a value chain network in a connected way such that connectivity was built around the intelligent product 1510 through a sensor, an IoT device, a tag, or another component.
  • the monitoring systems layer 614 may monitor any or all of the value chain entities 652 in a value chain network 668 , may exchange data with the value chain entities 652 , may provide control instructions to or take instructions from any of the value chain entities 652 , or the like, such as through the various capabilities of the data handling layers 608 described throughout this disclosure.
  • Each of the value chain network entities 652 may have a connection to the VCNP 604 , to a set of other value chain network entities 652 (which may be a local network connection, a peer-to-peer connection, a mobile network connection, a connection via a cloud, or other connection), and/or through the VCNP 604 to other value chain network entities 652 .
  • the value chain network management platform 604 may manage the connections, configure or provision resources to enable connectivity, and/or manage applications 630 that take advantage of the connections, such as by using information from one set of entities 652 to inform applications 630 involving another set of entities 652 , by coordinating activities of a set of entities 652 , by providing input to an artificial intelligence system of the VCNP 604 or of or about a set of entities 652 , by interacting with edge computation systems deployed on or in entities 652 and their environments, and the like.
  • the entities 652 may be external such that the VCNP 604 may interact with these entities 652 .
  • the VCNP 604 functions as the control tower to establish monitoring (e.g., establish monitoring such as common monitoring across several entities 652 ).
  • monitoring e.g., establish monitoring such as common monitoring across several entities 652 .
  • there may be an interface where a user may view various items such as user's destinations, ports, air and rail assets, as well as orders, etc.
  • the next step may be to establish a common data schema that enables services that work on or in any one of these applications. This may involve taking any of the data that is flowing through or about any of these entities 652 and pull the data into a framework where other applications across supply and demand may interact with the entities 652 .
  • a supplier may be bankrupt, or a determination is made that the supplier is bankrupt, and then the VCNP 604 may automatically trigger a substitute smart contract to be sent to a secondary supplier with altered terms.
  • a supplier may be bankrupt, or a determination is made that the supplier is bankrupt, and then the VCNP 604 may automatically trigger a substitute smart contract to be sent to a secondary supplier with altered terms.
  • There may be management of different aspects of the supply chain. For example, changing pricing instantly and automatically on the demand side in response to one more supplier's being identified as bankrupt (e.g., from bankruptcy announcement). Other similar examples may be used based on what occurs in that automation layer which may be enabled by the VCNP 604 .
  • a digital twin may be used by user to view all these entities 652 that are not typically shown together and monitor what is going on with each of these entities 652 including identification of problem states. For example, after viewing three quarters of bad financial reports on a supplier, a report may be flagged to watch it closely for potential future bankruptcy, etc.
  • an IoT system deployed in a fulfillment center 628 may coordinate with an intelligent product 1510 that takes customer feedback about the product 1510 , and an application 630 for the fulfillment center 628 may, upon receiving customer feedback via a connection path to the intelligent product 1510 about a problem with the product 1510 , initiate a workflow to perform corrective actions on similar products 650 before the products 650 are sent out from the fulfillment center 628 .
  • a port infrastructure facility 660 may inform a fleet of floating assets 620 via connections to the floating assets 620 (such as ships, barges, or the like) that the port is near capacity, thereby kicking off a negotiation process (which may include an automated negotiation based on a set of rules and governed by a smart contract) for the remaining capacity and enabling some assets 620 to be redirected to alternative ports or holding facilities.
  • the floating assets 620 such as ships, barges, or the like
  • the set of applications 614 provided on the VCNP 604 , integrated with the VCNP 604 and/or managed by or for the VCNP 604 and/or involving a set of value chain network entities 652 may include, without limitation, one or more of any of a wide range of types of applications, such as: a supply chain management applications 21004 (such as, without limitation, for management of timing, quantities, logistics, shipping, delivery, and other details of orders for goods, components, and other items); an asset management application 814 (such as, without limitation, for managing value chain assets, such as floating assets (such as ships, boats, barges, and floating platforms), real property (such as used for location of warehouses, ports, shipyards, distribution centers and other buildings), equipment, machines and fixtures (such as used for handling containers, cargo, packages, goods, and other items), vehicles (such as forklifts, delivery trucks, autonomous vehicles, and other systems used to move items), human resources (such as workers), software, information technology resources, data processing resources, data storage resources,
  • the value chain management platform 604 may host an enable interaction among a wide range of disparate applications 630 (such term including the above-referenced and other value chain applications, services, solutions, and the like), such that by virtue of shared microservices, shared data infrastructure, and shared intelligence, any pair or larger combination or permutation of such services may be improved relative to an isolated application of the same type.
  • disparate applications 630 such term including the above-referenced and other value chain applications, services, solutions, and the like
  • the set of applications 614 provided on the VCNP 604 , integrated with the VCNP 604 and/or managed by or for the VCNP 604 and/or involving a set of value chain network entities 652 may further include, without limitation: a payments application 860 (such as for calculating payments (including based on situational factors such as applicable taxes, duties and the like for the geography of an entity 652 ), transferring funds, resolving payments to parties, and the like, for any of the applications 630 noted herein); a process management application 862 (such as for managing any of the processes or workflows described throughout this disclosure, including supply processes, demand processes, logistics processes, delivery processes, fulfillment processes, distribution processes, ordering processes, navigation processes, and many others); a compatibility testing application 864 , such as for assessing compatibility among value chain network entities 652 or activities involved in any of the processes, workflows, activities, or other applications 630 described herein (such as for determining compatibility of a container or package with a product 1510
  • the set of applications 614 provided on the VCNP 604 , integrated with the VCNP 604 and/or managed by or for the VCNP 604 and/or involving a set of value chain network entities 652 may further include, without limitation: a predictive maintenance application 910 (such as for anticipating, predicting, and undertaking actions to manage faults, failures, shutdowns, damage, required maintenance, required repairs, required service, required support, or the like for a set of value chain network entities 652 , such as products 650 , equipment, infrastructure, buildings, vehicles, and others); a logistics application 912 (such as for managing logistics for pickups, deliveries, transfer of goods onto hauling facilities, loading, unloading, packing, picking, shipping, driving, and other activities involving in the scheduling and management of the movement of products 650 and other items between points of origin and points of destination through various intermediate locations; a reverse logistic application 914 (such as for handling logistics for returned products 650 , waste products, damaged goods, or other items that can be transferred on a predictive maintenance application 910 (such
  • the set of applications 614 provided on the VCNP 604 , integrated with the VCNP 604 and/or managed by or for the VCNP 604 and/or involving a set of value chain network entities 652 may further include, without limitation: a policy management application 868 (such as for deploying one or more policies, rules, or the like for governance of one or more value chain network entities 652 or applications 630 , such as to govern execution of one or more workflows (which may involve configuring polices in the platform 604 on a per-workflow basis), to govern compliance with regulations (including maritime, food and drug, medical, environmental, health, safety, tax, financial reporting, commercial, and other regulations as described throughout this disclosure or as would be understood in the art), to govern provisioning of resources (such as connectivity, computing, human, energy, and other resources), to govern compliance with corporate policies, to govern compliance with contracts (including smart contracts, wherein the platform 604 may automatically deploy governance features to relevant entities 652 and applications 630 , such as via connectivity facilities 642 .
  • the set of applications 614 provided on the VCNP 604 , integrated with the VCNP 604 and/or managed by or for the VCNP 604 and/or involving a set of value chain network entities 652 may further include, without limitation a maritime fleet management application 880 (for managing a set of maritime assets, such as container ships, barges, boats, and the like, as well as related infrastructure facilities such as docks, cranes, ports, and others, such as to determine optimal routes for fleet assets based on weather, market, traffic, and other conditions, to ensure compliance with policies and regulations, to ensure safety, to improve environmental factors, to improve financial metrics, and many others); a shipping management application 882 (such as for managing a set of shipping assets, such as trucks, trains, airplanes, and the like, such as to optimize financial yield, to improve safety, to reduce energy consumption, to reduce delays, to mitigate environmental impact, and for many other purposes); an opportunity matching application 884 (such as for matching one or more demand factors with one or more supply factors, for matching needs
  • a high-level schematic of an embodiment of the value chain network management platform 604 is illustrated, including a set of systems, applications, processes, modules, services, layers, devices, components, machines, products, sub-systems, interfaces, connections, and other elements working in coordination to enable intelligent management of sets of the value chain entities 652 that may occur, operate, transact or the like within, or own, operate, support or enable, one or more value chain network processes, workflows, activities, events and/or applications 630 or that may otherwise be part of, integrated with, linked to, or operated on by the platform 604 in connection with a product 1510 (which may be a finished good, software product, hardware product, component product, material, item of equipment, consumer packaged good, consumer product, food product, beverage product, home product, business supply product, consumable product, pharmaceutical product, medical device product, technology product, entertainment product, or any other type of product or related service, which may, in embodiments, encompass an intelligent product that is enabled with processing, networking, sensing, computation, and/or other Internet
  • Value chain entities 652 such as involved in or for a wide range of value chain activities (such as supply chain activities, logistics activities, demand management and planning activities, delivery activities, shipping activities, warehousing activities, distribution and fulfillment activities, inventory aggregation, storage and management activities, marketing activities, and many others, as involved in various value chain network processes, workflows, activities, events and applications 630 may include any of the wide variety of assets, systems, devices, machines, components, equipment, facilities, individuals or other entities mentioned throughout this disclosure or in the documents incorporated herein by reference.
  • value chain activities such as supply chain activities, logistics activities, demand management and planning activities, delivery activities, shipping activities, warehousing activities, distribution and fulfillment activities, inventory aggregation, storage and management activities, marketing activities, and many others, as involved in various value chain network processes, workflows, activities, events and applications 630 may include any of the wide variety of assets, systems, devices, machines, components, equipment, facilities, individuals or other entities mentioned throughout this disclosure or in the documents incorporated herein by reference.
  • the value chain network management platform 604 may include the set of data handling layers 608 , each of which is configured to provide a set of capabilities that facilitate development and deployment of intelligence, such as for facilitating automation, machine learning, applications of artificial intelligence, intelligent transactions, intelligent operations, remote control, analytics, monitoring, reporting, state management, event management, process management, and many others, for a wide variety of value chain network applications and end uses.
  • the data handling layers 608 may include a value chain network monitoring systems layer 614 , a value chain network entity-oriented data storage systems layer 624 (referred to in some cases herein for convenience simply as a data storage layer 624 ), an adaptive intelligent systems layer 614 and a value chain network management platform 604 .
  • the value chain network management platform 604 may include the data handling layers 608 such that the value chain network management platform 604 may provide management of the value chain network management platform 604 and/or management of the other layers such as the value chain network monitoring systems layer 614 , the value chain network entity-oriented data storage systems layer 624 (e.g., data storage layer 624 ), and the adaptive intelligent systems layer 614 .
  • Each of the data handling layers 608 may include a variety of services, programs, applications, workflows, systems, components and modules, as further described herein and in the documents incorporated herein by reference.
  • each of the data handling layers 608 (and optionally the platform 604 as a whole) is configured such that one or more of its elements can be accessed as a service by other layers 624 or by other systems (e.g., being configured as a platform-as-a-service deployed on a set of cloud infrastructure components in a microservices architecture).
  • the platform 604 may have (or may configure and/or provision), and a data handling layer 608 may use, a set of connectivity facilities 642 , such as network connections (including various configurations, types and protocols), interfaces, ports, application programming interfaces (APIs), brokers, services, connectors, wired or wireless communication links, human-accessible interfaces, software interfaces, micro-services, SaaS interfaces, PaaS interfaces, IaaS interfaces, cloud capabilities, or the like by which data or information may be exchanged between a data handling layer 608 and other layers, systems or sub-systems of the platform 604 , as well as with other systems, such as value chain entities 652 or external systems, such as cloud-based or on-premises enterprise systems (e.g., accounting systems, resource management systems, CRM systems, supply chain management systems and many others).
  • a set of connectivity facilities 642 such as network connections (including various configurations, types and protocols), interfaces, ports, application programming interfaces (APIs), brokers, services, connectors, wired
  • Each of the data handling layers 608 may include a set of services (e.g., microservices), for data handling, including facilities for data extraction, transformation and loading; data cleansing and deduplication facilities; data normalization facilities; data synchronization facilities; data security facilities; computational facilities (e.g., for performing pre-defined calculation operations on data streams and providing an output stream); compression and de-compression facilities; analytic facilities (such as providing automated production of data visualizations) and others.
  • services e.g., microservices
  • data handling including facilities for data extraction, transformation and loading; data cleansing and deduplication facilities; data normalization facilities; data synchronization facilities; data security facilities; computational facilities (e.g., for performing pre-defined calculation operations on data streams and providing an output stream); compression and de-compression facilities; analytic facilities (such as providing automated production of data visualizations) and others.
  • each data handling layer 608 has a set of application programming connectivity facilities 642 for automating data exchange with each of the other data handling layers 608 .
  • These may include data integration capabilities, such as for extracting, transforming, loading, normalizing, compression, decompressing, encoding, decoding, and otherwise processing data packets, signals, and other information as it exchanged among the layers and/or the applications 630 , such as transforming data from one format or protocol to another as needed in order for one layer to consume output from another.
  • the data handling layers 608 are configured in a topology that facilitates shared data collection and distribution across multiple applications and uses within the platform 604 by the value chain monitoring systems layer 614 .
  • the value chain monitoring systems layer 614 may include, integrate with, and/or cooperate with various data collection and management systems 640 , referred to for convenience in some cases as data collection systems 640 , for collecting and organizing data collected from or about value chain entities 652 , as well as data collected from or about the various data layers 624 or services or components thereof.
  • data collection systems 640 for collecting and organizing data collected from or about value chain entities 652 , as well as data collected from or about the various data layers 624 or services or components thereof.
  • a stream of physiological data from a wearable device worn by a worker undertaking a task or a consumer engaged in an activity can be distributed via the monitoring systems layer 614 to multiple distinct applications in the value chain management platform 604 , such as one that facilitates monitoring the physiological, psychological, performance level, attention, or other state of a worker and another that facilitates operational efficiency and/or effectiveness.
  • the monitoring systems layer 614 facilitates alignment, such as time-synchronization, normalization, or the like of data that is collected with respect to one or more value chain network entities 652 .
  • one or more video streams or other sensor data collected of or with respect to a worker 718 or other entity in a value chain network facility or environment, such as from a set of camera-enabled IoT devices may be aligned with a common clock, so that the relative timing of a set of videos or other data can be understood by systems that may process the videos, such as machine learning systems that operate on images in the videos, on changes between images in different frames of the video, or the like.
  • the monitoring systems layer 614 may further align a set of videos, camera images, sensor data, or the like, with other data, such as a stream of data from wearable devices, a stream of data produced by value chain network systems (such as ships, lifts, vehicles, containers, cargo handling systems, packing systems, delivery systems, drones/robots, and the like), a stream of data collected by mobile data collectors, and the like.
  • Configuration of the monitoring systems layer 614 as a common platform, or set of microservices, that are accessed across many applications may dramatically reduce the number of interconnections required by an owner or other operator within a value chain network in order to have a growing set of applications monitoring a growing set of IoT devices and other systems and devices that are under its control.
  • the data handling layers 608 are configured in a topology that facilitates shared or common data storage across multiple applications and uses of the platform 604 by the value chain network-oriented data storage systems layer 624 , referred to herein for convenience in some cases simply as the data storage layer 624 or storage layer 624 .
  • various data collected about the value chain entities 652 may be stored in the data storage layer 624 , such that any of the services, applications, programs, or the like of the various data handling layers 608 can access a common data source (which may comprise a single logical data source that is distributed across disparate physical and/or virtual storage locations).
  • a supply chain or inventory management application in the value chain management platform 604 may access the same data set about what parts have been replaced for a set of machines as a predictive maintenance application that is used to predict whether a component of a ship, or facility of a port is likely to require replacement parts.
  • prediction may be used with respect to the resupply of items.
  • value chain network data objects 1004 may be provided according to an object-oriented data model that defines classes, objects, attributes, parameters and other features of the set of data objects (such as associated with value chain network entities 652 and applications 630 ) that are handled by the platform 604 .
  • the data storage systems layer 624 may provide an extremely rich environment for collection of data that can be used for extraction of features or inputs for intelligence systems, such as expert systems, analytic systems, artificial intelligence systems, robotic process automation systems, machine learning systems, deep learning systems, supervised learning systems, or other intelligent systems as disclosed throughout this disclosure and the documents incorporated herein by reference.
  • intelligence systems such as expert systems, analytic systems, artificial intelligence systems, robotic process automation systems, machine learning systems, deep learning systems, supervised learning systems, or other intelligent systems as disclosed throughout this disclosure and the documents incorporated herein by reference.
  • each application 630 in the platform 604 and each adaptive intelligent system in the adaptive intelligent systems layer 614 can benefit from the data collected or produced by or for each of the others.
  • the data storage systems layer 624 may facilitate collection of data that can be used for extraction of features or inputs for intelligence systems such as a development framework from artificial intelligence.
  • the collections of data may pull in and/or house event logs (naturally stored or ad-hoc, as needed), perform periodic checks on onboard diagnostic data, or the like.
  • pre calculation of features may be deployed using AWS Lambda, for example, or various other cloud-based on-demand compute capabilities, such as pre-calculations, multiplexing signals.
  • there are pairings (doubles, triples, quadruplets, etc.) of similar kinds of value chain entities that may use one or more sets of capabilities of the data handling layers 608 to deploy connectivity and services across value chain entities and across applications used by the entities even when amassing hundreds and hundreds of data types from relatively disparate entities.
  • various pairings of similar types of value chain entities using, at least in part, the connectivity and services across value chain entities and applications may direct the information from the pairings of connected data to artificial intelligence services including the various neural networks disclosed herein and hybrid combinations thereof.
  • genetic programming techniques may be deployed to prune some of the input features in the information from the pairings of connected data.
  • genetic programming techniques may also be deployed to add to and augment the input features in the information from the pairings. These genetic programming techniques may be shown to increase the efficacy of the determinations established by the artificial intelligence services.
  • the information from the pairings of connected data may be migrated to other layers on the platform including to support or deploy robotic process automation, prediction, forecasting, and other resources such that the shared data schema may facilitate as capabilities and resources for the platform 604 .
  • a wide range of data types may be stored in the storage layer 624 using various storage media and data storage types, data architectures 1002 , and formats, including, without limitation: asset and facility data 1030 , state data 1140 (such as indicating a state, condition status, or other indicator with respect to any of the value chain network entities 652 , any of the applications 630 or components or workflows thereof, or any of the components or elements of the platform 604 , among others), worker data 1032 (including identity data, role data, task data, workflow data, health data, attention data, mood data, stress data, physiological data, performance data, quality data and many other types); event data 1034 ((such as with respect to any of a wide range of events, including operational data, transactional data, workflow data, maintenance data, and many other types of data that includes or relates to events that occur within a value chain network 668 or with respect to one or more applications 630 , including process events, financial events, transaction events, output events, input events, state-change events, operating events, workflow events, repair events, maintenance events
  • the data handling layers 608 are configured in a topology that facilitates shared adaptation capabilities, which may be provided, managed, mediated and the like by one or more of a set of services, components, programs, systems, or capabilities of the adaptive intelligent systems layer 614 , referred to in some cases herein for convenience as the adaptive intelligence layer 614 .
  • the adaptive intelligence systems layer 614 may include a set of data processing, artificial intelligence and computational systems 634 that are described in more detail elsewhere throughout this disclosure.
  • computing resources such as available processing cores, available servers, available edge computing resources, available on-device resources (for single devices or peered networks), and available cloud infrastructure, among others
  • data storage resources including local storage on devices, storage resources in or on value chain entities or environments (including on-device storage, storage on asset tags, local area network storage and the like), network storage resources, cloud-based storage resources, database resources and others), networking resources (including cellular network spectrum, wireless network resources, fixed network resources and others), energy resources (such as available battery power, available renewable energy, fuel, grid-based power, and many others) and others
  • energy resources such as available battery power, available renewable energy, fuel, grid-based power, and many others
  • others may be optimized in a coordinated or shared way on behalf of an operator, enterprise, or the like, such as for the benefit of multiple applications, programs, workflows, or the like.
  • the adaptive intelligence layer 614 may manage and provision available network resources for both a supply chain management application and for a demand planning application (among many other possibilities), such that low latency resources are used for supply chain management application (where rapid decisions may be important) and longer latency resources are used for the demand planning application.
  • a wide variety of adaptations may be provided on behalf of the various services and capabilities across the various layers 624 , including ones based on application requirements, quality of service, on-time delivery, service objectives, budgets, costs, pricing, risk factors, operational objectives, efficiency objectives, optimization parameters, returns on investment, profitability, uptime/downtime, worker utilization, and many others.
  • the value chain management platform 604 may include, integrate with, and enable the various value chain network processes, workflows, activities, events and applications 630 described throughout this disclosure that enable an operator to manage more than one aspect of a value chain network environment or entity 652 in a common application environment (e.g., shared, pooled, similarly licenses whether shared data for one person, multiple people, or anonymized), such as one that takes advantage of common data storage in the data storage layer 624 , common data collection or monitoring in the monitoring systems layer 614 and/or common adaptive intelligence of the adaptive intelligence layer 614 .
  • Outputs from the applications 630 in the platform 604 may be provided to the other data handing layers 624 .
  • state and status information for various objects, entities, processes, flows and the like; object information, such as identity, attribute and parameter information for various classes of objects of various data types; event and change information, such as for workflows, dynamic systems, processes, procedures, protocols, algorithms, and other flows, including timing information; outcome information, such as indications of success and failure, indications of process or milestone completion, indications of correct or incorrect predictions, indications of correct or incorrect labeling or classification, and success metrics (including relating to yield, engagement, return on investment, profitability, efficiency, timeliness, quality of service, quality of product, customer satisfaction, and others) among others.
  • Outputs from each application 630 can be stored in the data storage layer 624 , distributed for processing by the data collection layer 614 , and used by the adaptive intelligence layer 614 .
  • the cross-application nature of the platform 604 thus facilitates convenient organization of all of the necessary infrastructure elements for adding intelligence to any given application, such as by supplying machine learning on outcomes across applications, providing enrichment of automation of a given application via machine learning based on outcomes from other applications or other elements of the platform 604 , and allowing application developers to focus on application-native processes while benefiting from other capabilities of the platform 604 .
  • outputs and outcomes 1040 from various applications 630 may be used to facilitate automated learning and improvement of classification, prediction, or the like that is involved in a step of a process that is intended to be automated.
  • FIG. 12 additional details, components, sub-systems, and other elements of an optional embodiment of the data storage layer 624 of the platform 604 are illustrated.
  • Various data architectures may be used, including conventional relational and object-oriented data architectures, blockchain architectures 1180 , asset tag data storage architectures 1178 , local storage architectures 1190 , network storage architectures 1174 , multi-tenant architectures 1132 , distributed data architectures 1002 , value chain network (VCN) data object architectures 1004 , cluster-based architectures 1128 , event data-based architectures 1034 , state data-based architectures 1140 , graph database architectures 1124 , self-organizing architectures 1134 , and other data architectures 1002 .
  • VCN value chain network
  • the adaptive intelligent systems layer 614 of the platform 604 may include one or more protocol adaptors 1110 for facilitating data storage, retrieval access, query management, loading, extraction, normalization, and/or transformation to enable use of the various other data storage architectures 1002 , such as allowing extraction from one form of database and loading to a data system that uses a different protocol or data structure.
  • the value chain network-oriented data storage systems layer 624 may include, without limitation, physical storage systems, virtual storage systems, local storage systems (e.g., part of the local storage architectures 1190 ), distributed storage systems, databases, memory, network-based storage, network-attached storage systems (e.g., part of the network storage architectures 1174 such as using NVME, storage attached networks, and other network storage systems), and many others.
  • the storage layer 624 may store data in one or more knowledge graphs (such as a directed acyclic graph, a data map, a data hierarchy, a data cluster including links and nodes, a self-organizing map, or the like) in the graph database architectures 1124 .
  • the knowledge graph may be a prevalent example of when a graph database and graph database architecture may be used.
  • the knowledge graph may be used to graph a workflow. For a linear workflow, a directed acyclic graph may be used. For a contingent workflow, a cyclic graph may be used.
  • the graph database (e.g., graph database architectures 1124 ) may include the knowledge graph or the knowledge graph may be an example of the graph database.
  • the knowledge graph may include ontology and connections (e.g., relationships) between the ontology of the knowledge graph.
  • the knowledge graph may be used to capture an articulation of knowledge domains of a human expert such that there may be an identification of opportunities to design and build robotic process automation or other intelligence that may replicate this knowledge set.
  • the platform may be used to recognize that a type of expert is using this factual knowledge base (from the knowledge graph) coupled with competencies that may be replicable by artificial intelligence that may be different depending on type of expertise involved.
  • artificial intelligence such as a convolutional neural network may be used with spatiotemporal aspects that may be used to diagnose issues or packing up a box in a warehouse.
  • the platform may use a different type of knowledge graph for a self-organizing map of an expert whose main job is to segment customers into customer segmentation groups.
  • the knowledge graph may be built from various data such as job credentials, job listings, parsing output deliverables.
  • the data storage layer 624 may store data in a digital thread, ledger, or the like, such as for maintaining a serial or other records of an entities 652 over time, including any of the entities described herein.
  • the data storage layer 624 may use and enable an asset tag 1178 , which may include a data structure that is associated with an asset and accessible and managed, such as by use of access controls, so that storage and retrieval of data is optionally linked to local processes, but also optionally open to remote retrieval and storage options.
  • the storage layer 624 may include one or more blockchains 1180 , such as ones that store identity data, transaction data, historical interaction data, and the like, such as with access control that may be role-based or may be based on credentials associated with a value chain entity 652 , a service, or one or more applications 630 .
  • Data stored by the data storage systems 624 may include accounting and other financial data 730 , access data 734 , asset and facility data 1030 (such as for any of the value chain assets and facilities described herein), asset tag data 1178 , worker data 1032 , event data 1034 , risk management data 732 , pricing data 738 , safety data 664 and many other types of data that may be associated with, produced by, or produced about any of the value chain entities and activities described herein and in the documents incorporated by reference.
  • the management platform 604 may, in various optional embodiments, include the set of applications 614 , by which an operator or owner of a value chain network entity, or other users, may manage, monitor, control, analyze, or otherwise interact with one or more elements of a value chain network entity 652 , such as any of the elements noted in connection above and throughout this disclosure.
  • the adaptive intelligent systems layer 614 may include a set of systems, components, services and other capabilities that collectively facilitate the coordinated development and deployment of intelligent systems, such as ones that can enhance one or more of the applications 630 at the application platform 604 ; ones that can improve the performance of one or more of the components, or the overall performance (e.g., speed/latency, reliability, quality of service, cost reduction, or other factors) of the connectivity facilities 642 ; ones that can improve other capabilities within the adaptive intelligent systems layer 614 ; ones that improve the performance (e.g., speed/latency, energy utilization, storage capacity, storage efficiency, reliability, security, or the like) of one or more of the components, or the overall performance, of the value chain network-oriented data storage systems 624 ; ones that optimize control, automation, or one or more performance characteristics of one or more value chain network entities 652 ; or ones that generally improve any of the process and application outputs and outcomes 1040 pursued by use of the platform 604 .
  • intelligent systems such as ones that can enhance one or more of the applications 630 at
  • These adaptive intelligent systems 614 may include a robotic process automation system 1442 , a set of protocol adaptors 1110 , a packet acceleration system 1410 , an edge intelligence system 1420 (which may be a self-adaptive system), an adaptive networking system 1430 , a set of state and event managers 1450 , a set of opportunity miners 1460 , a set of artificial intelligence systems 1160 , a set of digital twin systems 1700 , a set of entity interaction systems 1920 (such as for setting up, provisioning, configuring and otherwise managing sets of interactions between and among sets of value chain network entities 652 in the value chain network 668 ), and other systems.
  • a robotic process automation system 1442 a set of protocol adaptors 1110 , a packet acceleration system 1410 , an edge intelligence system 1420 (which may be a self-adaptive system), an adaptive networking system 1430 , a set of state and event managers 1450 , a set of opportunity miners 1460 , a set of artificial intelligence systems 1160 , a set
  • the value chain monitoring systems layer 614 and its data collection systems 640 may include a wide range of systems for the collection of data.
  • This layer may include, without limitation, real time monitoring systems 1520 (such as onboard monitoring systems like event and status reporting systems on ships and other floating assets, on delivery vehicles, on trucks and other hauling assets, and in shipyards, ports, warehouses, distribution centers and other locations; on-board diagnostic (OBD) and telematics systems on floating assets, vehicles and equipment; systems providing diagnostic codes and events via an event bus, communication port, or other communication system; monitoring infrastructure (such as cameras, motion sensors, beacons, RFID systems, smart lighting systems, asset tracking systems, person tracking systems, and ambient sensing systems located in various environments where value chain activities and other events take place), as well as removable and replaceable monitoring systems, such as portable and mobile data collectors, RFID and other tag readers, smart phones, tablets and other mobile devices that are capable of data collection and the like); software interaction observation systems 1500 (such as for logging and tracking events involved in interactions of users with software user interfaces, such as mouse
  • the value chain monitoring systems layer 614 and its data collection systems 640 may include an entity discovery system 1900 for discovering one or more value chain network entities 652 , such as any of the entities described throughout this disclosure. This may include components or sub-systems for searching for entities within the value chain network 668 , such as by device identifier, by network location, by geolocation (such as by geofence), by indoor location (such as by proximity to known resources, such as IoT-enabled devices and infrastructure, Wifi routers, switches, or the like), by cellular location (such as by proximity to cellular towers), by identity management systems (such as where an entity 652 is associated with another entity 652 , such as an owner, operator, user, or enterprise by an identifier that is assigned by and/or managed by the platform 604 ), and the like. Entity discovery 1900 may initiate a handshake among a set of devices, such as to initiate interactions that serve various applications 630 or other capabilities of the platform 604 .
  • a management platform of an information technology system such as a management platform for a value chain of goods and/or services is depicted as a block diagram of functional elements and representative interconnections.
  • the management platform includes a user interface 3020 that provides, among other things, a set of adaptive intelligence systems 614 .
  • the adaptive intelligence systems 614 provide coordinated intelligence (including artificial intelligence 1160 , expert systems 3002 , machine learning 3004 , and the like) for a set of demand management applications 824 and for a set of supply chain applications 812 for a category of goods 3010 , which may be produced and sold through the value chain.
  • the adaptive intelligence systems 614 may deliver artificial intelligence 1160 through a set of data processing, artificial intelligence and computational systems 634 .
  • the adaptive intelligence systems 614 are selectable and/or configurable through the user interface 3020 so that one or more of the adaptive intelligence systems 614 can operate on or in cooperation with the sets of value chain applications (e.g., demand management applications 824 and supply chain applications 812 ).
  • the adaptive intelligence systems 614 may include artificial intelligence, including any of the various expert systems, artificial intelligence systems, neural networks, supervised learning systems, machine learning systems, deep learning systems, and other systems described throughout this disclosure and in the documents incorporated by reference.
  • user interface may include interfaces for configuring an artificial intelligence system 1160 to take inputs from selected data sources of the value chain (such as data sources used by the set of demand management applications 824 and/or the set of supply chain applications 812 ) and supply them, such as to a neural network, artificial intelligence system 1160 or any of the other adaptive intelligence systems 614 described throughout this disclosure and in the documents incorporated herein by reference to enhance, control, improve, optimize, configure, adapt or have another impact on a value chain for the category of goods 3010 .
  • the selected data sources of the value chain may be applied either as inputs for classification or prediction, or as outcomes relating to the value chain, the category of goods 3010 and the like.
  • providing coordinated intelligence may include providing artificial intelligence capabilities, such as artificial intelligence systems 1160 and the like.
  • Artificial intelligence systems may facilitate coordinated intelligence for the set of demand management applications 824 or the set of supply chain applications 812 or both, such as for a category of goods, such as by processing data that is available in any of the data sources of the value chain, such as value chain processes, bills of materials, manifests, delivery schedules, weather data, traffic data, goods design specifications, customer complaint logs, customer reviews, Enterprise Resource Planning (ERP) System, Customer Relationship Management (CRM) System, Customer Experience Management (CEM) System, Service Lifecycle Management (SLM) System, Product Lifecycle Management (PLM) System, and the like.
  • ERP Enterprise Resource Planning
  • CRM Customer Relationship Management
  • CEM Customer Experience Management
  • SLM Service Lifecycle Management
  • PLM Product Lifecycle Management
  • the user interface 3020 may provide access to, among other things artificial intelligence capabilities, applications, systems and the like for coordinating intelligence for applications of the value chain and particularly for value chain applications for the category of goods 3010 .
  • the user interface 3020 may be adapted to receive information descriptive of the category of goods 3010 and configure user access to the artificial intelligence capabilities responsive thereto, so that the user, through the user interface is guided to artificial intelligence capabilities that are suitable for use with value chain applications (e.g., the set of demand management applications 824 and supply chain applications 812 ) that contribute to goods/services in the category of goods 3010 .
  • the user interface 3020 may facilitate providing coordinated intelligence that comprises artificial intelligence capabilities that provide coordinated intelligence for a specific operator and/or enterprise that participates in the supply chain for the category of goods.
  • the user interface 3020 may be configured to facilitate the user selecting and/or configuring multiple artificial intelligence systems 1160 for use with the value chain.
  • the user interface may present the set of demand management applications 824 and supply chain applications 812 as connected entities that receive, process, and produce outputs each of which may be shared among the applications.
  • Types of artificial intelligence systems 1160 may be indicated in the user interface 3020 responsive to sets of connected applications or their data elements being indicated in the user interface, such as by the user placing a pointer proximal to a connected set of applications and the like.
  • the user interface 3020 may facilitate access to the set of adaptive intelligence systems provides a set of capabilities that facilitate development and deployment of intelligence for at least one function selected from a list of functions consisting of supply chain application automation, demand management application automation, machine learning, artificial intelligence, intelligent transactions, intelligent operations, remote control, analytics, monitoring, reporting, state management, event management, and process management.
  • the adaptive intelligence systems 614 may be configured with data processing, artificial intelligence and computational systems 634 that may operate cooperatively to provide coordinated intelligence, such as when an artificial intelligence system 1160 operates on or responds to data collected by or produced by other systems of the adaptive intelligence systems 614 , such as a data processing system and the like.
  • providing coordinated intelligence may include operating a portion of a set of artificial intelligence systems 1160 that employs one or more types of neural network that is described herein and in the documents incorporated herein by reference and that processes any of the demand management application outputs and supply chain application outputs to provide the coordinated intelligence.
  • providing coordinated intelligence for the set of demand management applications 824 may include configuring at least one of the adaptive intelligence systems 614 (e.g., through the user interface 3020 and the like) for at least one or more demand management applications selected from a list of demand management applications including a demand planning application, a demand prediction application, a sales application, a future demand aggregation application, a marketing application, an advertising application, an e-commerce application, a marketing analytics application, a customer relationship management application, a search engine optimization application, a sales management application, an advertising network application, a behavioral tracking application, a marketing analytics application, a location-based product or service-targeting application, a collaborative filtering application, a recommendation engine for a product or service, and the like.
  • providing coordinated intelligence for the set of supply chain applications 812 may include configuring at least one of the adaptive intelligence systems 614 for at least one or more supply chain applications selected from a list of supply chain applications including a goods timing management application, a goods quantity management application, a logistics management application, a shipping application, a delivery application, an order for goods management application, an order for components management application, and the like.
  • the management platform 102 may, such as through the user interface 3020 facilitate access to the set of adaptive intelligence systems 614 that provide coordinated intelligence for a set of demand management applications 824 and supply chain applications 812 through the application of artificial intelligence.
  • the user may seek to align supply with demand while ensuring profitability and the like of a value chain for a category of goods 3010 .
  • the management platform allows the user to focus on the applications of demand and supply while gaining advantages of techniques such as expert systems, artificial intelligence systems, neural networks, supervised learning systems, machine learning systems, deep learning systems, and the like.
  • the management platform 102 may, through the user interface 3020 and the like provide a set of adaptive intelligence systems 614 that provide coordinated artificial intelligence 1160 for the sets of demand management applications 824 and supply chain applications 812 for the category of goods 3020 by, for example, determining (automatically) relationships among demand management and supply chain applications based on inputs used by the applications, results produced by the applications, and value chain outcomes.
  • the artificial intelligence 1160 may be coordinated by, for example, the set of data processing, artificial intelligence and computational systems 634 available through the adaptive intelligence systems 614 .
  • the management platform 102 may be configured with a set of artificial intelligence systems 1160 as part of a set of adaptive intelligence systems 614 that provide the coordinated intelligence for the sets of demand management applications 824 and supply chain applications 812 for a category of goods 3010 .
  • the set of artificial intelligence systems 1160 may provide the coordinated intelligence so that at least one supply chain application of the set of supply chain applications 812 produces results that address at least one aspect of supply for at least one of the goods in the category of goods as determined by at least one demand management application of the set of demand management applications 824 .
  • a behavioral tracking demand management application may generate results for behavior of uses of a good in the category of goods 3010 .
  • the artificial intelligence systems 1160 may process the behavior data and conclude that there is a perceived need for greater consumer access to a second product in the category of goods 3010 .
  • This coordinated intelligence may be, optionally automatically, applied to the set of supply chain applications 812 so that, for example, production resources or other resources in the value chain for the category of goods are allocated to the second product.
  • a distributor who handles stocking retailer shelves may receive a new stocking plan that allocates more retail shelf space for the second product, such as by taking away space from a lower margin product and the like.
  • the set of artificial intelligence systems 1160 and the like may provide coordinated intelligence for the sets of supply chain and demand management applications by, for example, determining an optionally temporal prioritization of demand management application outputs that impact control of supply chain applications so that an optionally temporal demand for at least one of the goods in the category of goods 3010 can be met.
  • Seasonal adjustments in prioritization of demand application results are one example of a temporal change. Adjustments in prioritization may also be localized, such as when a large college football team is playing at their home stadium and local supply of tailgating supplies may temporally be adjusted even though demand management application results suggest that small propane stoves are not currently in demand in a wider region.
  • a set of adaptive intelligence systems 614 that provide coordinated intelligence, such as by providing artificial intelligence capabilities 1160 and the like may also facilitate development and deployment of intelligence for at least one function selected from a list of functions consisting of supply chain application automation, demand management application automation, machine learning, artificial intelligence, intelligent transactions, intelligent operations, remote control, analytics, monitoring, reporting, state management, event management, and process management.
  • the set of adaptive intelligence systems 614 may be configured as a layer in the platform and an artificial intelligence system therein may operate on or be responsive to data collected by and/or produced by other systems (e.g., data processing systems, expert systems, machine learning systems and the like) of the adaptive intelligence systems layer.
  • the coordinated intelligence may be provided for a specific value chain entity 652 , such as a supply chain operator, business, enterprise, and the like that participates in the supply chain for the category of goods.
  • a specific value chain entity 652 such as a supply chain operator, business, enterprise, and the like that participates in the supply chain for the category of goods.
  • Providing coordinated intelligence may include employing a neural network to process at least one of the inputs and outputs of the sets of demand management and supply chain applications.
  • Neural networks may be used with demand applications, such as a demand planning application, a demand prediction application, a sales application, a future demand aggregation application, a marketing application, an advertising application, an e-commerce application, a marketing analytics application, a customer relationship management application, a search engine optimization application, a sales management application, an advertising network application, a behavioral tracking application, a marketing analytics application, a location-based product or service-targeting application, a collaborative filtering application, a recommendation engine for a product or service, and the like.
  • Neural networks may also be used with supply chain applications such as a goods timing management application, a goods quantity management application, a logistics management application, a shipping application, a delivery application, an order for goods management application, an order for components management application, and the like.
  • Neural networks may provide coordinated intelligence by processing data that is available in any of a plurality of value chain data sources for the category of goods including without limitation processes, bill of materials, weather, traffic, design specification, customer complaint logs, customer reviews, Enterprise Resource Planning (ERP) System, Customer Relationship Management (CRM) System, Customer Experience Management (CEM) System, Service Lifecycle Management (SLM) System, Product Lifecycle Management (PLM) System, and the like.
  • ERP Enterprise Resource Planning
  • CRM Customer Relationship Management
  • CEM Customer Experience Management
  • SLM Service Lifecycle Management
  • PLM Product Lifecycle Management
  • Neural networks configured for providing coordinated intelligence may share adaptation capabilities with other adaptive intelligence systems 614 , such as when these systems are configured in a topology that facilitates such shared adaptation.
  • neural networks may facilitate provisioning available value chain/supply chain network resources for both the set of demand management applications and for the set of supply chain applications.
  • neural networks may provide coordinated intelligence to improve at least one of the list of outputs consisting of a process output, an application output, a process outcome, an application outcome, and the like.
  • a management platform of an information technology system such as a management platform for a value chain of goods and/or services is depicted as a block diagram of functional elements and representative interconnections.
  • the management platform includes a user interface 3020 that provides, among other things, a hybrid set of adaptive intelligence systems 614 .
  • the hybrid set of adaptive intelligence systems 614 provide coordinated intelligence through the application of artificial intelligence, such as through application of a hybrid artificial intelligence system 3060 , and optionally through one or more expert systems, machine learning systems, and the like for use with a set of demand management applications 824 and for a set of supply chain applications 812 for a category of goods 3010 , which may be produced and sold through the value chain.
  • the hybrid adaptive intelligence systems 614 may deliver two types of artificial intelligence systems, type A 3052 and type B 3054 through a set of data processing, artificial intelligence and computational systems 634 .
  • the hybrid adaptive intelligence systems 614 are selectable and/or configurable through the user interface 3020 so that one or more of the hybrid adaptive intelligence systems 614 can operate on or in cooperation with the sets of supply chain applications (e.g., demand management applications 824 and supply chain applications 812 ).
  • the hybrid adaptive intelligence systems 614 may include a hybrid artificial intelligence system 3060 that may include at least two types of artificial intelligence capabilities including any of the various expert systems, artificial intelligence systems, neural networks, supervised learning systems, machine learning systems, deep learning systems, and other systems described throughout this disclosure and in the documents incorporated by reference.
  • the hybrid adaptive intelligence systems 614 may facilitate applying a first type of artificial intelligence system 1160 to the set of demand management applications 824 and a second type of artificial intelligence system 1160 to the set of supply chain applications 812 , wherein each of the first type and second type of artificial intelligence system 1160 can operate independently, cooperatively, and optionally coordinate operation to provide coordinated intelligence for operation of the value chain that produces at least one of the goods in the category of goods 3010 .
  • the user interface 3020 may include interfaces for configuring a hybrid artificial intelligence system 3060 to take inputs from selected data sources of the value chain (such as data sources used by the set of demand management applications 824 and/or the set of supply chain applications 812 ) and supply them, such as to at least one of the two types of artificial intelligence systems in the hybrid artificial intelligence system 3060 , types of which are described throughout this disclosure and in the documents incorporated herein by reference to enhance, control, improve, optimize, configure, adapt or have another impact on a value chain for the category of goods 3010 .
  • the selected data sources of the value chain may be applied either as inputs for classification or prediction, or as outcomes relating to the value chain, the category of goods 3010 and the like.
  • the hybrid adaptive intelligence systems 614 provides a plurality of distinct artificial intelligence systems 1160 , a hybrid artificial intelligence system 3060 , and combinations thereof.
  • any of the plurality of distinct artificial intelligence systems 1160 and the hybrid artificial intelligence system 3060 may be configured as a plurality of neural network-based systems, such as a classification-adapted neural network, a prediction-adapted neural network and the like.
  • a machine learning-based artificial intelligence system may be provided for the set of demand management applications 824 and a neural network-based artificial intelligence system may be provided for the set of supply chain applications 812 .
  • the hybrid adaptive intelligence systems 614 may provide the hybrid artificial intelligence system 3060 that may include a first type of artificial intelligence that is applied to the demand management applications 824 and which is distinct from a second type of artificial intelligence that is applied to the supply chain applications 812 .
  • a hybrid artificial intelligence system 3060 may include any combination of types of artificial intelligence systems including a plurality of a first type of artificial intelligence (e.g., neural networks) and at least one second type of artificial intelligence (e.g., an expert system) and the like.
  • a hybrid artificial intelligence system may comprise a hybrid neural network that applies a first type of neural network with respect to the demand management applications 824 and a second type of neural network with respect to the supply chain applications 812 .
  • a hybrid artificial intelligence system 3060 may provide two types of artificial intelligence to different applications, such as different demand management applications 824 (e.g., a sales management application and a demand prediction application) or different supply chain applications 812 (e.g., a logistics control application and a production quality control application).
  • different demand management applications 824 e.g., a sales management application and a demand prediction application
  • different supply chain applications 812 e.g., a logistics control application and a production quality control application.
  • hybrid adaptive intelligence systems 614 may be applied as distinct artificial intelligence capabilities to distinct demand management applications 824 .
  • coordinated intelligence through a hybrid artificial intelligence capabilities may be provided to a demand planning application by a feed-forward neural network, to a demand prediction application by a machine learning system, to a sales application by a self-organizing neural network, to a future demand aggregation application by a radial basis function neural network, to a marketing application by a convolutional neural network, to an advertising application by a recurrent neural network, to an e-commerce application by a hierarchical neural network, to a marketing analytics application by a stochastic neural network, to a customer relationship management application by an associative neural network and the like.
  • a management platform of an information technology system such as a management platform for a value chain of goods and/or services is depicted as a block diagram of functional elements and representative interconnections for providing a set of predictions 3070 .
  • the management platform includes a user interface 3020 that provides, among other things, a set of adaptive intelligence systems 614 .
  • the adaptive intelligence systems 614 provide a set of predictions 3070 through the application of artificial intelligence, such as through application of an artificial intelligence system 1160 , and optionally through one or more expert systems, machine learning systems, and the like for use with a coordinated set of demand management applications 824 and supply chain applications 812 for a category of goods 3010 , which may be produced and sold through the value chain.
  • the adaptive intelligence systems 614 may deliver the set of prediction 3070 through a set of data processing, artificial intelligence and computational systems 634 .
  • the adaptive intelligence systems 614 are selectable and/or configurable through the user interface 3020 so that one or more of the adaptive intelligence systems 614 can operate on or in cooperation with the coordinated sets of value chain applications.
  • the adaptive intelligence systems 614 may include an artificial intelligence system that provides artificial intelligence capabilities known to be associated with artificial intelligence including any of the various expert systems, artificial intelligence systems, neural networks, supervised learning systems, machine learning systems, deep learning systems, and other systems described throughout this disclosure and in the documents incorporated by reference.
  • the adaptive intelligence systems 614 may facilitate applying adapted intelligence capabilities to the coordinated set of demand management applications 824 and supply chain applications 812 such as by producing a set of predictions 3070 that may facilitate coordinating the two sets of value chain applications, or at least facilitate coordinating at least one demand management application and at least one supply chain application from their respective sets.
  • the set of predictions 3070 includes a least one prediction of an impact on a supply chain application based on a current state of a coordinated demand management application, such as a prediction that a demand for a good will decrease earlier than previously anticipated.
  • the set of predictions 3070 includes at least one prediction of an impact on a demand management application based on a current state of a coordinated supply chain application, such as a prediction that a lack of supply of a good will likely impact a measure of demand of related goods.
  • the set of predictions 3070 is a set of predictions of adjustments in supply required to meet demand Other predictions include at least one prediction of change in demand that impacts supply.
  • predictions in the set of predictions predict a change in supply that impacts at least one of the set of demand management applications, such as a promotion application for at least one good in the category of goods.
  • a prediction in the set of predictions may be as simple as setting a likelihood that a supply of a good in the category of goods will not meet demand set by a demand setting application.
  • the adaptive intelligence systems 614 may provide a set of artificial intelligence capabilities to facilitate providing the set of predictions for the coordinated set of demand management applications and supply chain applications.
  • the set of artificial intelligence capabilities may include a probabilistic neural network that may be used to predict a fault condition or a problem state of a demand management application such as a lack of sufficient validated feedback.
  • the probabilistic neural network may be used to predict a problem state with a machine performing a value chain operation (e.g., a production machine, an automated handling machine, a packaging machine, a shipping machine and the like) based on a collection of machine operating information and preventive maintenance information for the machine.
  • the set of predictions 3070 may be provided by the management platform 102 directly through a set of adaptive artificial intelligence systems.
  • the set of predictions 3070 may be provided for the coordinated set of demand management applications and supply chain applications for a category of goods by applying artificial intelligence capabilities for coordinating the set of demand management applications and supply chain applications.
  • the set of predictions 3070 may be predictions of outcomes for operating a value chain with the coordinated set demand management applications and supply chain applications for the category of goods, so that a user may conduct test cases of coordinated sets of demand management applications and supply chain applications to determine which sets may produce desirable outcomes (viable candidates for a coordinated set of applications) and which may produce undesirable outcomes.
  • a management platform of an information technology system such as a management platform for a value chain of goods and/or services is depicted as a block diagram of functional elements and representative interconnections for providing a set of classifications 3080 .
  • the management platform includes a user interface 3020 that provides, among other things, a set of adaptive intelligence systems 614 .
  • the adaptive intelligence systems 614 provide a set of classifications 3080 through, for example, the application of artificial intelligence, such as through application of an artificial intelligence system 1160 , and optionally through one or more expert systems, machine learning systems, and the like for use with a coordinated set of demand management applications 824 and supply chain applications 812 for a category of goods 3010 , which may be produced, marketed, sold, resold, rented, leased, given away, serviced, recycled, renewed, enhanced, and the like through the value chain.
  • the adaptive intelligence systems 614 may deliver the set of classifications 3080 through a set of data processing, artificial intelligence and computational systems 634 .
  • the adaptive intelligence systems 614 are selectable and/or configurable through the user interface 3020 so that one or more of the adaptive intelligence systems 614 can operate on or in cooperation with the coordinated sets of value chain applications.
  • the adaptive intelligence systems 614 may include an artificial intelligence system that provides, among other things classification capabilities through any of the various expert systems, artificial intelligence systems, neural networks, supervised learning systems, machine learning systems, deep learning systems, and other systems described throughout this disclosure and in the documents incorporated by reference.
  • the adaptive intelligence systems 614 may facilitate applying adapted intelligence capabilities to the coordinated set of demand management applications 824 and supply chain applications 812 such as by producing a set of classifications 3080 that may facilitate coordinating the two sets of value chain applications, or at least facilitate coordinating at least one demand management application and at least one supply chain application from their respective sets.
  • the set of classifications 3080 includes at least one classification of a current state of a supply chain application for use by a coordinated demand management application, such as a classification of a problem state that may impact operation of a demand management application, such as a marketing application and the like. Such a classification may be useful in determining how to adjust a market expectation for a good that is going to have a lower yield than previously anticipated. The converse may also be true in that the set of classifications 3080 includes at least one classification of a current state of a demand management application and its relationship to a coordinated supply chain application.
  • the set of classifications 3080 is a set of classifications of adjustments in supply required to meet demand, such as adjustments to production worker needs would be classified differently that adjustments in third-party logistics providers.
  • classifications may include at least one classification of perceived changes in demand and a resulting potential impact on supply management.
  • classifications in the set of classifications may include a supply chain application impact on at least one of the set of demand management applications, such as a promotion application for at least one good in the category of goods.
  • a classification in the set of classifications may be as simple as classifying a likelihood that a supply of a good in the category of goods will not meet demand set by a demand setting application.
  • the adaptive intelligence systems 614 may provide a set of artificial intelligence capabilities to facilitate providing the set of classifications 3080 for the coordinated set of demand management applications and supply chain applications.
  • the set of artificial intelligence capabilities may include a probabilistic neural network that may be used to classify fault conditions or problem states of a demand management application, such as a classification of a lack of sufficient validated feedback.
  • the probabilistic neural network may be used to classify a problem state of a machine performing a value chain operation (e.g., a production machine, an automated handling machine, a packaging machine, a shipping machine and the like) as pertaining to at least one of machine operating information and preventive maintenance information for the machine.
  • the set of classifications 3080 may be provided by the management platform 102 directly through a set of adaptive artificial intelligence systems. Further, the set of classifications 3080 may be provided for the coordinated set of demand management applications and supply chain applications for a category of goods by applying artificial intelligence capabilities for coordinating the set of demand management applications and supply chain applications.
  • the set of classifications 3080 may be classifications of outcomes for operating a value chain with the coordinated set demand management applications and supply chain applications for the category of goods, so that a user may conduct test cases of coordinated sets of demand management applications and supply chain applications to determine which sets may produce outcomes that are classified as desirable (e.g., viable candidates for a coordinated set of applications) and outcomes that are classified as undesirable.
  • the set of classifications may comprise a set of adaptive intelligence functions, such as a neural network that may be adapted to classify information associated with the category of goods.
  • the neural network may be a multilayered feed forward neural network.
  • performing classifications may include classifying discovered value chain entities as one of demand centric and supply centric.
  • the set of classifications 3080 may be achieved through use of artificial intelligence systems 1160 for coordinating the set of coordinated demand management and supply chain applications. Artificial intelligence systems may configure and generate sets of classifications 3080 as a means by which demand management applications and supply chain applications can be coordinated. In an example, classification of information flow throughout a value chain may be classified as being relevant to both a demand management application and a supply chain application; this common relevance may be a point of coordination among the applications. In embodiments, the set of classifications may be artificial intelligence generated classifications of outcomes of operating a supply chain that is dependent on the coordinated demand management applications 824 and supply chain applications 812 .
  • a management platform of an information technology system such as a management platform for a value chain of goods and/or services is depicted as a block diagram of functional elements and representative interconnections for achieving automated control intelligence.
  • the management platform includes a user interface 3020 that provides, among other things, a set of adaptive intelligence systems 614 .
  • the adaptive intelligence systems 614 provide automated control signaling 3092 for a coordinated set of demand management applications 824 and supply chain applications 812 for a category of goods 3010 , which may be produced and sold through the value chain.
  • the adaptive intelligence systems 614 may deliver the automated control signals 3092 through a set of data processing, artificial intelligence and computational systems 634 .
  • the adaptive intelligence systems 614 are selectable and/or configurable through the user interface 3020 so that one or more of the adaptive intelligence systems 614 can automatically control the sets of supply chain applications (e.g., demand management applications 824 and supply chain applications 812 ).
  • the adaptive intelligence systems 614 may include artificial intelligence including any of the various expert systems, artificial intelligence systems, neural networks, supervised learning systems, machine learning systems, deep learning systems, and other systems described throughout this disclosure and in the documents incorporated by reference.
  • the user interface 3020 may include interfaces for configuring an adaptive intelligence systems 614 to take inputs from selected data sources of the value chain 3094 (such as data sources used by the coordinated set of demand management applications 824 and/or the set of supply chain applications 812 ) and supply them, such as to a neural network, artificial intelligence system 1160 or any of the other adaptive intelligence systems 614 described throughout this disclosure and in the documents incorporated herein by reference for producing automated control signals 3092 , such as to enhance, control, improve, optimize, configure, adapt or have another impact on a value chain for the category of goods 3010 .
  • the selected data sources of the value chain may be used for determining aspects of the automated control signals, such as for temporal adjustments to control outcomes relating to the value chain at least for the category of goods 3010 and the like.
  • the set of automated control signals may include at least one control signal for automating execution of a supply chain application, such as a production start, an automated material order, an inventory check, a billing application and the like in the coordinated set of demand management applications and supply chain applications.
  • the set of automated control signals may include at least one control signal for automating execution of a demand management application, such as a product recall application, an email distribution application and the like in the coordinated set of demand management applications and supply chain applications.
  • the automate control signals may control timing of demand management applications based on goods supply status.
  • the adaptive intelligence systems 614 may apply machine learning to outcomes of supply to automatically adapt a set of demand management application control signals. Similarly, the adaptive intelligence systems 614 may apply machine learning to outcomes of demand management to automatically adapt a set of supply chain application control signals.
  • the adaptive intelligence systems 614 may provide further processing for automated control signal generation, such as by applying artificial intelligence to determine aspects of a value chain that impact automated control of the coordinated set of demand management applications and supply chain applications for a category of goods. The determined aspects could be used in the generation and operation of automated control intelligence/signals, such as by filtering out value chain information for aspects that do not impact the targeted demand management and supply chain applications.
  • Automated control of, for example, supply chain applications may be restricted, such as by policy, operational limits, safety constraints and the like.
  • the set of adaptive intelligence systems may determine a range of supply chain application control values within which control can be automated.
  • the range may be associated with a supply rate, a supply timing rate, a mix of goods in a category of goods, and the like.
  • Embodiments are described herein for using artificial intelligence systems or capabilities to identify, configure and regulate automated control signals.
  • Such embodiments may further include a closed loop of feedback from the coordinated set of demand management and supply chain applications (e.g., state information, output information, outcomes and the like) that is optionally processed with machine learning and used to adapt the automated control signals for at least one of the goods in the category of goods.
  • An automated control signal may be adapted based on, for example, an indication of feedback from a supply chain application that yield of a good suggests a production problem.
  • the automated control signal may impact production rate and the feedback may cause the signal to automatically self-adjust to a slower production rate until the production problem is resolved.
  • a management platform of an information technology system such as a management platform for a value chain of goods and/or services is depicted as a block diagram of functional elements and representative interconnections for providing information routing recommendations.
  • the management platform includes a set of value chain networks 3102 from which network data 3110 is collected from a set of information routing activities, the information including outcomes, parameters, routing activity information and the like. Within the set of value chain networks 3102 is selected a select value chain network 3104 for which at least one information routing recommendation 3130 is provided.
  • An artificial intelligence system 1160 may include a machine learning system and may be trained using a training set derived from the network data 3110 outcomes, parameters and routing activity information for the set of value chain networks 3102 .
  • the artificial intelligence system 1160 may further provide an information routing recommendation 3130 based on a current status 3120 of the select value chain network 3104 .
  • the artificial intelligence system may use machine learning to train on information transaction types within the set of value chain networks 3102 , thereby learning pertinent factors regarding different transaction types (e.g., real-time inventory updates, buyer credit checks, engineering signoff, and the like) and contributing to the information routing recommendation accordingly.
  • the artificial intelligence system may also use machine learning to train on information value for different types and/or classes of information routed in and throughout the set of value chain networks 3102 .
  • Information may be valued on a wide range of factors, including timing of information availability and timing of information consumption as well as information content-based value, such as information without which a value chain network element (e.g., a production provider) cannot perform a desired action (e.g., starting volume production without a work order). Therefore information routing recommendations may be based on training on transaction type, information value, and a combination thereof. These are merely exemplary information routing recommendation training and recommendation basis factors and are presented here without limitation on other elements for training and recommendation basis.
  • the artificial intelligence system 1160 may provide an information routing recommendation 3130 based on transaction type, transaction type and information type, network type and the like.
  • An information routing recommendation may be based on combinations of factors, such as information type and network type, such as when an information type (streaming) is not compatible with a network type (small transactions).
  • the artificial intelligence system 1160 may use machine learning to develop an understanding of networks within the selected value chain network 3104 , such as network topology, network loading, network reliability, network latency and the like. This understanding may be combined with, for example, detected or anticipated network conditions to form an information routing recommendation. Aspects such as existence of edge intelligence in a value chain network 3104 can influence one or more information routing recommendations.
  • a type of information may be incompatible with a network type; however the network may be configured with edge intelligence that can be leveraged by the artificial intelligence system 1160 to adapt the form of the information being routed so that it is compatible with a targeted network type.
  • an information routing recommendation may impact information routing recommendations.
  • an information routing recommendation may avoid routing information that is confidential to a first supplier in the value chain through network nodes controlled by competitors of the supplier.
  • an information routing recommendation may include routing information to a first node where it is partially consumed and partially processed for further routing, such as by splitting up the portion partially processed for further routing into destination-specific information sets.
  • an artificial intelligence system 1160 may provide an information routing recommendation based on goals, such as goals of a value chain network, goals of information routing, and the like.
  • Goal-based information routing recommendations may include routing goals, such as Quality of Service routing goals, routing reliability goals (which may be measured based on a transmission failure rate and the like). Other goals may include a measure of latency associated with one or more candidate routes.
  • An information routing recommendation may be based on the availability of information in a selected value chain network, such as when information is available and when it needs to be delivered. For information that is available well ahead of when it is needed (e.g., a nightly production report that is available for routing at 2 AM is first needed by 7 AM), routing recommendations may include using resources that are lower cost, may involve short delays in routing and the like. For information that is available just before it is needed (e.g., a result of product testing is needed within a few hundred milliseconds of when the test is finished to maintain a production operation rate, and the like).
  • An information routing recommendation may be formed by the artificial intelligence system 1160 based on information persistence factors, such as how long information is available for immediate routing within the value chain network.
  • information persistence factors such as how long information is available for immediate routing within the value chain network.
  • An information routing recommendation that factors information persistence may select network resources based on availability, cost and the like during a time of information persistence.
  • Information value and an impact on information value may factor into an information routing recommendation.
  • information that is valid for a single shipment e.g., a production run of a good
  • an information routing recommendation may indicate routing the relevant information to all of the highest priority consumers of the information while it is still valid.
  • routing of information that is consumed by more than one value chain entity may need to be coordinated so that each value chain entity receives the information at a desired time/moment, such as during the same production shift, at their start of day, which may be different if the entities are in different time zones, and the like.
  • information routing recommendations may be based on a topology of a value chain, based on location and availability of network storage resources, and the like.
  • one or more information routing recommendations may be adapted while the information is routed based on, for example, changes in network resource availability, network resource discovery, network dynamic loading, priority of recommendations that are generated after information for a first recommendation is in-route, and the like.
  • a management platform of an information technology system such as a management platform for a value chain of goods and/or services is depicted as a block diagram of functional elements and representative interconnections for semi-sentient problem recognitions of pain points in a value chain network.
  • the management platform includes a set of value chain network entities 3152 from which entity-related data 3160 is collected and includes outcomes, parameters, activity information and the like associated with the entities.
  • entity-related data 3160 is collected and includes outcomes, parameters, activity information and the like associated with the entities.
  • select value chain network entities 3154 for which at least one pain point problem state 3172 is detected.
  • An artificial intelligence system 1160 may be training on a training set derived from the entity-related data 3160 including training on outcomes associated with value chain entities, parameters associated with, for example, operation of the value chain, value chain activity information and the like.
  • the artificial intelligence system may further employ machine learning to facilitate learning problem state factors 3180 that may characterize problem states input as training data. These factors 3180 may further be used by an instance of artificial intelligence 1160 ′ that operates on computing resources 3170 that are local to value chain network entities that are experiencing the problem/result of a pain point.
  • a goal of such a configuration of artificial intelligence systems, data sets, and value chain networks is to recognize a problem state in a portion of the selected value chain.
  • recognizing problem states may be based on variance analysis, such as variances that occur in value chain measures (e.g., loading, latency, delivery time, cost, and the like), particularly in a specific measure over time. Variances that exceed a variance threshold (e.g., an optionally dynamic range of results of a value chain operation, such as production, shipping, clearing customs, and the like) may be indicative of a pain point.
  • variances that occur in value chain measures e.g., loading, latency, delivery time, cost, and the like
  • a variance threshold e.g., an optionally dynamic range of results of a value chain operation, such as production, shipping, clearing customs, and the like
  • the platform 102 In addition to detecting problem states, the platform 102 , such as through the methods of semi-sentient problem recognition, predict a pain point based at least in part on a correlation with a detected problem state.
  • the correlation may be derived from the value chain, such as a shipper cannot deliver international goods until they are processed through customs, or a sales forecast cannot be provided with a high degree of confidence without high quality field data and the like.
  • a predicted pain point may be a point of value chain activity further along a supply chain, an activity that occurs in a related activity (e.g., tax planning is related to tax laws), and the like.
  • a predicted pain point may be assigned a risk value based on aspects of the detected problem state and correlations between the predicted pain point activity and the problem state activity.
  • a problem state with one of the suppliers may indicate a low risk of a pain point of use of the material.
  • a demand management application indicates high demand for a good and a problem is detected with information on which the demand is based, a risk of excess inventory (pain point) may be high depending on, for example how far along in the value chain the good has progressed.
  • semi-sentient problem recognition may involve more than mere linkages of data and operational states of entities engaged in a value chain. Problem recognition may also be based on human factors, such as perceived stress of production supervisors, shippers, and the like. Human factors for use in semi-sentient problem recognition may be collected from sensors that facilitate detection of human stress level and the like (e.g., wearable physiological sensors, and the like).
  • semi-sentient problem recognition may also be based on unstructured information, such as digital communication, voice messaging, and the like that may be shared among, originate with, or be received by humans involved in the value chain operations.
  • unstructured information such as digital communication, voice messaging, and the like that may be shared among, originate with, or be received by humans involved in the value chain operations.
  • natural language processing of email communications among workers in an enterprise may indicate a degree of discomfort with, for example, a supplier to a value chain. While data associated with the supplier (e.g., on-time production, quality, and the like) may be within a variance range deemed acceptable, information within this unstructured content may indicate a potential pain point, such as a personal issue with a key participant at the supplier and the like.
  • semi-sentient problem recognition may be based on analysis of variances of measures of a value chain operation/entity/application including variance of a given measure over time, variance of two related measures, and the like.
  • variance in outcomes over time may indicate a problem state and/or suggest a pain point.
  • an artificial intelligence-based system may determine an acceptable range of outcome variance and apply that range to measures of a select set of value chain network entities, such as entities that share one or more similarities, to facilitate detection of a problem state.
  • an acceptable range of outcome variance may indicate a problem state trigger threshold that may be used by a local instance of artificial intelligence to signal a problem state.
  • a problem state may be detected when at least one measure of the value chain activity/entity and the like is greater than the artificial intelligence-determined problem state threshold.
  • Variance analysis for problem state detection may include detecting variances in start/end times of scheduled value chain network entity activities, variances in at least one of production time, production quality, production rate, production start time, production resource availability or trends thereof, variances in a measure of shipping supply chain entity, variances in a duration of time for transfer from one mode of transport to another (e.g., when the variance is greater than a transport mode problem state threshold), variances in quality testing, and the like.
  • a semi-sentient problem recognition system may include a machine learning/artificial intelligence prediction of a correlated pain point further along a supply chain due to a detected pain point, such as a risk and/or need for overtime, expedited shipping, discounting goods prices, and the like.
  • a machine learning/artificial intelligence system may process outcomes, parameters, and data collected from a set of data sources relating to a set of value chain entities and activities to detect at least one pain point selected from the list of pain points consisting of late shipment, damaged container, damaged goods, wrong goods, customs delay, unpaid duties, weather event, damaged infrastructure, blocked waterway, incompatible infrastructure, congested port, congested handling infrastructure, congested roadway, congested distribution center, rejected goods, returned goods, waste material, wasted energy, wasted labor force, untrained workforce, poor customer service, empty transport vehicle on return route, excessive fuel prices, excessive tariffs, and the like.
  • a management platform of an information technology system such as a management platform for a value chain of goods and/or services is depicted as a block diagram of functional elements and representative interconnections automated coordination of a set of value chain network activities for a set of products of an enterprise.
  • the management platform includes a set of network-connected value chain network entities 3202 that produce activity information 3208 that is used by an artificial intelligence system 1160 to provide automate coordination 3220 of value chain network activities 3212 for a set of products 3210 for an enterprise 3204 .
  • value chain monitoring systems 614 may monitor activities of the set of network-connected value chain entities 3202 and work cooperatively with data collection and management systems 640 to gather and store value chain entity monitored information, such as activity information, configuration information, and the like. This gathered information may be configured as activity information 3208 for a set of activities associated with a set of products 3210 of an enterprise 3204 .
  • the artificial intelligence systems 1160 may use application programming connectivity facilities 642 for automating access to the monitored activity information 3208 .
  • a value chain may include a plurality of interconnected entities that each perform several activities for completing the value chain. While humans play a critical role in some activities within a value chain network, greater automated coordination and unified orchestration of supply and demand may be achieved using artificial intelligence-type systems (e.g., machine learning, expert systems, self-organizing systems, and the like including such systems describe herein and in the documents incorporated herein by reference) for coordinating supply chain activities.
  • artificial intelligence may further enrich the emerging nature of self-adapting systems, including Internet of Things (IoT) devices and intelligent products and the like that not only provide greater capabilities to end users, but can play a critical role in automated coordination of supply chain activities.
  • IoT Internet of Things
  • an IoT system deployed in a fulfillment center 628 may coordinate with an intelligent product 1510 that takes customer feedback about the product 1510 , and an application 630 for the fulfillment center 628 may, upon receiving customer feedback via a connection path to the intelligent product 1510 about a problem with the product 1510 , initiate a workflow to perform corrective actions on similar products 650 before the products 650 are sent out from the fulfillment center 628 .
  • the workflow may be configured by an artificial intelligence system 1160 that analyzes the problem with the product 1510 , develops an understanding of value chain network activities that produce the product, determines resources required for the workflow, coordinates with inventory and production systems to adapt any existing workflows and the like. Artificial intelligence systems 1160 may further coordinate with demand management applications to address any temporary impact on product availability and the like.
  • automated coordination of a set of value chain network activities for a set of products for an enterprise may rely on the methods and systems of coordinated intelligence described herein, such as to facilitate coordinating demand management activities, supply chain activities and the like, optionally using artificial intelligence for providing the coordinated intelligence, coordinating the activities and the like.
  • artificial intelligence may facilitate determining relationships among value change network activities based on inputs used by the activities and results produced by the activities.
  • Artificial intelligence may be integrated with and/or work cooperatively with activities of the platform, such as value chain network entity activities to continuously monitor activities, identify temporal aspects needing coordination (e.g., when changes in supply temporally impact demand activities), and automate such coordination.
  • Automated coordination of value chain network activities within and across value chain network entity activities may benefit from advanced artificial intelligence systems that may enable use of differing artificial intelligence capabilities for any given value chain set of entities, applications, or conditions.
  • Use of hybrid artificial intelligence systems may provide benefits by applying more than one type of intelligence to a set of conditions to facilitate human and/or computer automated selection thereof.
  • Artificial intelligence can further enhance automated coordination of value chain network entity activities through intelligent operations such as generating sets of predictions, sets of classifications, generation of automate control signals (that may be communicated across value chain network entities and the like).
  • Artificial intelligence systems may facilitate automated coordination of value chain network entity activities for a set of products or an enterprise based on adaptive intelligence provided by the platform for a category of goods under which the set of products of an enterprise may be grouped.
  • adaptive intelligence may be provided by the platform for a drapery hanging category of goods and a set of products for an enterprise may include a line of adaptable drapery hangers.
  • artificial intelligence capabilities may be applied to value chain network activities of the enterprise for automating aspects of the value chain, such as information exchange among activities and the like.
  • the adaptive intelligence layer 614 may include a value chain network digital twin system 1700 , which may include a set of components, processes, services, interfaces and other elements for development and deployment of digital twin capabilities for visualization of various value chain entities 652 , environments, and applications 630 , as well as for coordinated intelligence (including artificial intelligence 1160 , edge intelligence 1400 , analytics and other capabilities) and other value-added services and capabilities that are enabled or facilitated with a digital twin 1700 .
  • a digital twin 1700 may be used for and/or applied to each of the processes that are managed, controlled, or mediated by each of the set of applications 614 of the platform application layer.
  • the digital twin 1700 may take advantage of the presence of multiple applications 630 within the value chain management platform 604 , such that a pair of applications may share data sources (such as in the data storage layer 624 ) and other inputs (such as from the monitoring layer 614 ) that are collected with respect to value chain entities 652 , as well as sharing outputs, events, state information and outputs, which collectively may provide a much richer environment for enriching content in a digital twin 1700 , including through use of artificial intelligence 1160 (including any of the various expert systems, artificial intelligence systems, neural networks, supervised learning systems, machine learning systems, deep learning systems, and other systems described throughout this disclosure and in the documents incorporated by reference) and through use of content collected by the monitoring layer 614 and data collection systems 640 .
  • artificial intelligence 1160 including any of the various expert systems, artificial intelligence systems, neural networks, supervised learning systems, machine learning systems, deep learning systems, and other systems described throughout this disclosure and in the documents incorporated by reference
  • a digital twin 1700 may be used in connection with shared or converged processes among the various pairs of the applications 630 of the application 604 , such as, without limitation, of a converged process involving a security application 834 and an inventory management application 820 , integrated automation of blockchain-based applications 844 with facility management applications 850 , and many others.
  • converged processes may include shared data structures for multiple applications 630 (including ones that track the same transactions on a blockchain but may consume different subsets of available attributes of the data objects maintained in the blockchain or ones that use a set of nodes and links in a common knowledge graph) that may be connected to with the digital twin 1700 such that the digital twin 1700 is updated accordingly.
  • a transaction indicating a change of ownership of an entity 652 may be stored in a blockchain and used by multiple applications 630 , such as to enable role-based access control, role-based permissions for remote control, identity-based event reporting, and the like that may be connected to and shared with the digital twin 1700 such that the digital twin 1700 may be updated accordingly.
  • converged processes may include shared process flows across applications 630 , including subsets of larger flows that are involved in one or more of a set of applications 614 that may be connected to and shared with the digital twin 1700 such that the digital twin 1700 may be updated accordingly.
  • an inspection flow about a value chain network entity 652 may serve an analytics solution 838 , an asset management solution 814 , and others.
  • a digital twin 1700 may be provided for the wide range of value chain network applications 630 mentioned throughout this disclosure and the documents incorporated herein by reference.
  • An environment for development of a digital twin 1700 may include a set of interfaces for developers in which a developer may configure an artificial intelligence system 1160 to take inputs from selected data sources of the data storage layer 624 and events or other data from the monitoring systems layer 614 and supply them for inclusion in a digital twin 1700 .
  • a digital twin 1700 development environment may be configured to take outputs and outcomes from various applications 630 .
  • any of the value chain network entities 652 can be depicted in a set of one or more digital twins 1700 , such as by populating the digital twin 1700 with value chain network data object 1004 , such as event data 1034 , state data 1140 , or other data with respect to value chain network entities 652 , applications 630 , or components or elements of the platform 604 as described throughout this disclosure.
  • the platform 604 may include, integrate, integrate with, manage, control, coordinate with, or otherwise handle any of a wide variety of digital twins 1700 , such as distribution twins 1714 (such as representing distribution facilities, assets, objects, workers, or the like); warehousing twins 1712 (such as representing warehouse facilities, assets, objects, workers and the like); port infrastructure twins 1714 (such as representing a seaport, an airport, or other facility, as well as assets, objects, workers and the like); shipping facility twins 1720 ; operating facility twins 1722 ; customer twins 1730 (such as representing physical, behavioral, demographic, psychographic, financial, historical, affinity, interest, and other characteristics of groups of customers or individual customers); worker twins 1740 (such as representing physical attributes, physiologic data, status data, psychographic information, emotional states, states of fatigue/energy, states of attention, skills, training, competencies, roles, authority, responsibilities, work status, activities, and other attributes of or involving workers); wearable/portable device twins 1750 ; process twins 1760
  • Each of these may have characteristics of digital twins described throughout this disclosure and the documents incorporated by reference herein, such as mirroring or reflecting changes in states of associated physical objects or other entities, providing capabilities for modeling behavior or interactions of associated physical objects or other entities, enabling simulations, providing indications of status, and many others.
  • a digital twin system may be configured to generate a variety of enterprise digital twins 1700 in connection with a value chain (e.g., specifically value chain network entities 652 ).
  • a value chain e.g., specifically value chain network entities 652 .
  • an enterprise that produces goods internationally (or at multiple facilities) may configure a set of digital twins 1700 , such as supplier twins that depict the enterprise's supply chain, factory twins of the various production facilities, product twins that represent the products made by the enterprise, distribution twins that represent the enterprise's distribution chains, and other suitable twins.
  • the enterprise may define the structural elements of each respective digital twin as well as any system data that corresponds to the structural elements of the digital twin.
  • the enterprise may the layout and spatial definitions of the facility and any processes that are performed in the facility.
  • the enterprise may also define data sources corresponding to the value chain network entities 652 , such as sensor systems, smart manufacturing equipment, inventory systems, logistics systems, and the like that provide data relevant to the facility.
  • the enterprise may associate the data sources with elements of the production facility and/or the processes occurring the facility.
  • the enterprise may define the structural, process, and layout definitions of its supply chain and its distribution chain and may connect relevant data sources, such as supplier databases, logistics platforms, to generate respective distribution chain and supply chain twins.
  • the enterprise may further associate these digital twins to have a view of its value chain.
  • the digital twin system may perform simulations of the enterprise's value chain that incorporate real-time data obtained from the various value chain network entities 652 of the enterprise.
  • the digital twin system may recommend decisions to a user interacting with the enterprise digital twins 1700 , such as when to order certain parts for manufacturing a certain product given a predicted demand for the manufactured product, when to schedule maintenance on machinery and/or replace machinery (e.g., when digital simulations on the digital twin indicates the demand for certain products may be the lowest or when it would have the least effect on the enterprise's profits and losses statement), what time of day to ship items, or the like.
  • the foregoing example is a non-limiting example of the manner by which a digital twin may ingest system data and perform simulations in order to further one or more goals.
  • the monitoring systems layer 614 may include a set of entity discovery systems 1900 , such as for identifying sets of value chain network entities 652 , identifying types of value chain network entities 652 , identifying specific value chain network entities 652 and the like, as well as for managing identities of the value chain network entities 652 , including for resolving ambiguities (such as where a single entity is identified differently in different systems, where different entities are identified similarly, and the like), for entity identity deduplication, for entity identity resolution, for entity identity enhancement (such as by enriching data objects with additional data that is collected about an entity within the platform), and the like.
  • entity discovery systems 1900 such as for identifying sets of value chain network entities 652 , identifying types of value chain network entities 652 , identifying specific value chain network entities 652 and the like, as well as for managing identities of the value chain network entities 652 , including for resolving ambiguities (such as where a single entity is identified differently in different systems, where different entities are identified similarly, and the like), for entity identity deduplication,
  • Entity discovery 1900 may also include discovery of interactions among entities, such as how entities are connected (e.g., by what network connections, data integration systems, and/or interfaces), what data is exchanged among entities (including what types of data objects are exchanged, what common workflows involve entities, what inputs and outputs are exchanged between entities, and the like), what rules or policies govern the entities, and the like.
  • the platform 604 may include a set of entity interaction management systems 1902 , which may comprise one or more artificial intelligence systems (including any of the types described throughout this disclosure) for managing a set of interactions among entities that are discovered through entity discovery 1900 , including ones that learn on a training set of data to manage interactions among entities based on how entities have been managed by human supervisors or by other systems.
  • the entity discovery system 1900 may be used to discover a network-connected camera that shows the loading dock of facility that produces a product for an enterprise, as well as to identify what interfaces or protocols are needed to access a feed of video content from the camera.
  • the entity interaction management system 1902 may then be used to interact with the interfaces or protocols to set up access to the feed and to provide the feed to another system for further processing, such as to have an artificial intelligence system 1160 process the feed to discovery content that is relevant to an activity of the enterprise.
  • the artificial intelligence system 1160 may process image frames of the video feed to find markings (such as produce labels, SKUs, images, logos, or the like), shapes (such as packages of a particular size or shape), activities (such as loading or unloading activities) or the like that may indicate that a product has moved through the loading dock.
  • markings such as produce labels, SKUs, images, logos, or the like
  • shapes such as packages of a particular size or shape
  • activities such as loading or unloading activities
  • This information may substitute for, augment, or be used to validate other information, such as RFID tracking information or the like.
  • Similar discovery and interaction management activities may be undertaken with any of the types of value chain network entities 652 described throughout this disclosure.
  • the adaptive intelligence layer 614 may include a robotic process automation (RPA) system 1442 , which may include a set of components, processes, services, interfaces and other elements for development and deployment of automation capabilities for various value chain entities 652 , environments, and applications 630 .
  • RPA robotic process automation
  • robotic process automation 1442 may be applied to each of the processes that are managed, controlled, or mediated by each of the set of applications 614 of the platform application layer, to functions, components, workflows, processes of the VCNP 604 itself, to processes involving value chain network entities 652 and other processes.
  • robotic process automation 1442 may take advantage of the presence of multiple applications 630 within the value chain management platform 604 , such that a pair of applications may share data sources (such as in the data storage layer 624 ) and other inputs (such as from the monitoring layer 614 ) that are collected with respect to value chain entities 652 , as well as sharing outputs, events, state information and outputs, which collectively may provide a much richer environment for process automation, including through use of artificial intelligence 1160 (including any of the various expert systems, artificial intelligence systems, neural networks, supervised learning systems, machine learning systems, deep learning systems, and other systems described throughout this disclosure and in the documents incorporated by reference).
  • artificial intelligence 1160 including any of the various expert systems, artificial intelligence systems, neural networks, supervised learning systems, machine learning systems, deep learning systems, and other systems described throughout this disclosure and in the documents incorporated by reference).
  • an asset management application 814 may use robotic process automation 1442 for automation of an asset inspection process that is normally performed or supervised by a human (such as by automating a process involving visual inspection using video or still images from a camera or other that displays images of an entity 652 , such as where the robotic process automation 1442 system is trained to automate the inspection by observing interactions of a set of human inspectors or supervisors with an interface that is used to identify, diagnose, measure, parameterize, or otherwise characterize possible defects or favorable characteristics of a facility or other asset.
  • robotic process automation 1442 for automation of an asset inspection process that is normally performed or supervised by a human (such as by automating a process involving visual inspection using video or still images from a camera or other that displays images of an entity 652 , such as where the robotic process automation 1442 system is trained to automate the inspection by observing interactions of a set of human inspectors or supervisors with an interface that is used to identify, diagnose, measure, parameterize, or otherwise characterize possible defects or favorable characteristics of a facility or other asset.
  • interactions of the human inspectors or supervisors may include a labeled data set where labels or tags indicate types of defects, favorable properties, or other characteristics, such that a machine learning system can learn, using the training data set, to identify the same characteristics, which in turn can be used to automate the inspection process such that defects or favorable properties are automatically classified and detected in a set of video or still images, which in turn can be used within the value chain network asset management application 814 to flag items that require further inspection, that should be rejected, that should be disclosed to a prospective buyer, that should be remediated, or the like.
  • robotic process automation 1442 may involve multi-application or cross-application sharing of inputs, data structures, data sources, events, states, outputs or outcomes.
  • the asset management application 814 may receive information from a marketplace application 854 that may enrich the robotic process automation 1442 of the asset management application 814 , such as information about the current characteristics of an item from a particular vendor in the supply chain for an asset, which may assist in populating the characteristics about the asset for purposes of facilitating an inspection process, a negotiation process, a delivery process, or the like.
  • a marketplace application 854 may enrich the robotic process automation 1442 of the asset management application 814 , such as information about the current characteristics of an item from a particular vendor in the supply chain for an asset, which may assist in populating the characteristics about the asset for purposes of facilitating an inspection process, a negotiation process, a delivery process, or the like.
  • Robotic process automation 1442 may be used with various functionality of the VCNP 604 .
  • robotic process automation 1442 may be described as training a robot to operate and automate a task that was, to at least a large extent, governed by a human.
  • One of these tasks may be used to train a robot that may train other robots.
  • the robotic process automation 1442 may be trained (e.g., through machine learning) to mimic interactions on a training set, and then have this trained robotic process automation 1442 (e.g., trained agent or trained robotic process automation system) execute these tasks that were previously performed by people.
  • the robotic process automation 1442 may utilize software that may provide software interaction observations (such as mouse movements, mouse clicks, cursor movements, navigation actions, menu selections, keyboard typing, and many others), such as logged and/or tracked by software interaction observation system 1500 , purchase of the product by a customer 714 , and the like. This may include monitoring of a user's mouse clicks, mouse movements, and/or keyboard typing to learn to do the same clicks and/or typing.
  • the robotic process automation 1442 may utilize software to learn physical interactions with robots and other systems to train a robotic system to sequence or undertake the same physical interactions. For example, the robot may be trained to rebuild a set of bearings by having the robot watch a video of someone doing this task. This may include tracking physical interactions and tracking interactions at a software level.
  • the robotic process automation 1442 may understand what the underlying competencies are that are being deployed such that the VCNP 604 preconfigure combinations of neural networks that may be used to replicate performance of human capabilities.
  • robotic process automation may be applied to shared or converged processes among the various pairs of the applications 630 of the application 604 , such as, without limitation, of a converged process involving a security application 834 and an inventory application 820 , integrated automation of blockchain-based applications 844 with vendor management applications 832 , and many others.
  • converged processes may include shared data structures for multiple applications 630 (including ones that track the same transactions on a blockchain but may consume different subsets of available attributes of the data objects maintained in the blockchain or ones that use a set of nodes and links in a common knowledge graph).
  • a transaction indicating a change of ownership of an entity 652 may be stored in a blockchain and used by multiple applications 630 , such as to enable role-based access control, role-based permissions for remote control, identity-based event reporting, and the like.
  • converged processes may include shared process flows across applications 630 , including subsets of larger flows that are involved in one or more of a set of applications 614 .
  • a risk management or inspection flow about an entity 652 may serve an inventory management application 832 , an asset management application 814 , a demand management application 824 , and a supply chain application 812 , among others.
  • robotic process automation 1442 may be provided for the wide range of value chain network processes mentioned throughout this disclosure and the documents incorporated herein by reference, including without limitation all of the applications 630 .
  • An environment for development of robotic process automation for value chain networks may include a set of interfaces for developers in which a developer may configure an artificial intelligence system 1160 to take inputs from selected data sources of the VCN data storage layer 624 and event data 1034 , state data 1140 or other value chain network data objects 1004 from the monitoring systems layer 614 and supply them, such as to a neural network, either as inputs for classification or prediction, or as outcomes relating to the platform 102 , value chain network entities 652 , applications 630 , or the like.
  • the RPA development environment 1442 may be configured to take outputs and outcomes 1040 from various applications 630 , again to facilitate automated learning and improvement of classification, prediction, or the like that is involved in a step of a process that is intended to be automated.
  • the development environment, and the resulting robotic process automation 1442 may involve monitoring a combination of both software program interaction observations 1500 (e.g., by workers interacting with various software interfaces of applications 630 involving value chain network entities 652 ) and physical process interaction observations 1510 (e.g., by watching workers interacting with or using machines, equipment, tools or the like in a value chain network 668 ).
  • observation of software interactions 1500 may include interactions among software components with other software components, such as how one application 630 interacts via APIs with another application 630 .
  • observation of physical process interactions 1510 may include observation (such as by video cameras, motion detectors, or other sensors, as well as detection of positions, movements, or the like of hardware, such as robotic hardware) of how human workers interact with value chain entities 652 (such as locations of workers (including routes taken through a location, where workers of a given type are located during a given set of events, processes or the like, how workers manipulate pieces of equipment, cargo, containers, packages, products 650 or other items using various tools, equipment, and physical interfaces, the timing of worker responses with respect to various events (such as responses to alerts and warnings), procedures by which workers undertake scheduled deliveries, movements, maintenance, updates, repairs and service processes; procedures by which workers tune or adjust items involved in workflows, and many others).
  • value chain entities 652 such as locations of workers (including routes taken through a location, where workers of a given type are located during a given set of events
  • Physical process observation 1510 may include tracking positions, angles, forces, velocities, acceleration, pressures, torque, and the like of a worker as the worker operates on hardware, such as on a container or package, or on a piece of equipment involved in handling products, with a tool. Such observations may be obtained by any combination of video data, data detected within a machine (such as of positions of elements of the machine detected and reported by position detectors), data collected by a wearable device (such as an exoskeleton that contains position detectors, force detectors, torque detectors and the like that is configured to detect the physical characteristics of interactions of a human worker with a hardware item for purposes of developing a training data set).
  • the RPA system 1442 can more comprehensively automate processes involving value chain entities 652 , such as by using software automation in combination with physical robots.
  • robotic process automation 1442 is configured to train a set of physical robots that have hardware elements that facilitate undertaking tasks that are conventionally performed by humans. These may include robots that walk (including walking up and down stairs to deliver a package), climb (such as climbing ladders in a warehouse to reach shelves where products 650 are stored), move about a facility, attach to items, grip items (such as using robotic arms, hands, pincers, or the like), lift items, carry items, remove and replace items, use tools and many others.
  • an information technology system may include a cloud-based management VCNP 604 with a micro-services architecture, a set of interfaces 702 , a set of network connectivity facilities 642 , adaptive intelligence facilities 614 , data storage facilities 624 , data collection systems 640 , and monitoring facilities 614 that are coordinated for monitoring and management of a set of value chain network entities 652 ; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a unified set of robotic process automation systems 1442 that provide coordinated automation among various applications 630 , including demand management applications, supply chain applications, intelligent product applications and enterprise resource management applications for a category of goods.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a unified set of robotic process automation systems that provide coordinated automation among at least two types of applications from among a set of demand management applications, a set of supply chain applications, a set of intelligent product applications and a set of enterprise resource management applications for a category of goods.
  • an information technology system may include a cloud-based management VCNP 102 with a micro-services architecture, a set of interfaces 702 , a set of network connectivity facilities 642 , adaptive intelligence facilities 614 , data storage facilities 624 , data collection systems 640 , and monitoring facilities 614 that are coordinated for monitoring and management of a set of value chain network entities 652 ; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a set of microservices layers including an application layer supporting at least one supply chain application and at least one demand management application, wherein the microservice layers include a robotic process automation layer 1442 that uses information collected by a data collection layer 640 and a set of outcomes and activities 1040 involving the applications of the application layer 630 to automate a set of actions for at least a subset of the applications 630 .
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a set of microservices layers including an application layer supporting at least one supply chain application and at least one demand management application, wherein the microservice layers include a robotic process automation layer that uses information collected by a data collection layer and a set of outcomes and activities involving the applications of the application layer to automate a set of actions for at least a subset of the applications.
  • an information technology system may include a cloud-based management VCNP 102 with a micro-services architecture, a set of interfaces 702 , a set of network connectivity facilities 642 , adaptive intelligence facilities 614 , data storage facilities 624 , data collection systems 640 , and monitoring facilities 614 that are coordinated for monitoring and management of a set of value chain network entities 652 ; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a set of robotic process automation systems 1442 for automating a set of processes in a value chain network, wherein the robotic process automation systems 1442 learn on a training set of data involving a set of user interactions with a set of interfaces 702 of a set of software systems that are used to monitor and manage the value chain network entities 652 , as well as from various process and application outputs and outcomes 1040 that may occur with or within the VCNP 102
  • the value chain network entities 652 may include, for example, products, suppliers, producers, manufacturers, retailers, businesses, owners, operators, operating facilities, customers, consumers, workers, mobile devices, wearable devices, distributors, resellers, supply chain infrastructure facilities, supply chain processes, logistics processes, reverse logistics processes, demand prediction processes, demand management processes, demand aggregation processes, machines, ships, barges, warehouses, maritime ports, airports, airways, waterways, roadways, railways, bridges, tunnels, online retailers, ecommerce sites, demand factors, supply factors, delivery systems, floating assets, points of origin, points of destination, points of storage, points of use, networks, information technology systems, software platforms, distribution centers, fulfillment centers, containers, container handling facilities, customs, export control, border control, drones, robots, autonomous vehicles, hauling facilities, drones/robots/AVs, waterways, port infrastructure facilities, or many others.
  • the robotic process automation layer automates a process that may include, for example, without limitation, selection of a quantity of product for an order, selection of a carrier for a shipment, selection of a vendor for a component, selection of a vendor for a finished goods order, selection of a variation of a product for marketing, selection of an assortment of goods for a shelf, determination of a price for a finished good, configuration of a service offer related to a product, configuration of product bundle, configuration of a product kit, configuration of a product package, configuration of a product display, configuration of a product image, configuration of a product description, configuration of a website navigation path related to a product, determination of an inventory level for a product, selection of a logistics type, configuration of a schedule for product delivery, configuration of a logistics schedule, configuration of a set of inputs for machine learning, preparation of product documentation, preparation of required disclosures about a product, configuration of a product for a set of local requirements, configuration of a set of products for compatibility, configuration of a
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; and a set of robotic process automation systems for automating a set of processes in a value chain network, wherein the robotic process automation systems learn on a training set of data involving a set of user interactions with a set of interfaces of a set of software systems that are used to monitor and manage the value chain network entities.
  • one of the processes automated by robotic process automation as described in any of the embodiments disclosed herein may involve the following.
  • RPA involves selection of a quantity of product for an order.
  • one of the processes automated by robotic process automation involves selection of a carrier for a shipment.
  • one of the processes automated by robotic process automation involves selection of a vendor for a component.
  • one of the processes automated by robotic process automation involves selection of a vendor for a finished goods order.
  • one of the processes automated by robotic process automation involves selection of a variation of a product for marketing.
  • one of the processes automated by robotic process automation involves selection of an assortment of goods for a shelf.
  • one of the processes automated by robotic process automation involves determination of a price for a finished good. In embodiments, one of the processes automated by robotic process automation involves configuration of a service offer related to a product. In embodiments, one of the processes automated by robotic process automation involves configuration of product bundle. In embodiments, one of the processes automated by robotic process automation involves configuration of a product kit. In embodiments, one of the processes automated by robotic process automation involves configuration of a product package. In embodiments, one of the processes automated by robotic process automation involves configuration of a product display. In embodiments, one of the processes automated by robotic process automation involves configuration of a product image. In embodiments, one of the processes automated by robotic process automation involves configuration of a product description.
  • one of the processes automated by robotic process automation involves configuration of a website navigation path related to a product. In embodiments, one of the processes automated by robotic process automation involves determination of an inventory level for a product. In embodiments, one of the processes automated by robotic process automation involves selection of a logistics type. In embodiments, one of the processes automated by robotic process automation involves configuration of a schedule for product delivery. In embodiments, one of the processes automated by robotic process automation involves configuration of a logistics schedule. In embodiments, one of the processes automated by robotic process automation involves configuration of a set of inputs for machine learning. In embodiments, one of the processes automated by robotic process automation involves preparation of product documentation. In embodiments, one of the processes automated by robotic process automation involves preparation of required disclosures about a product.
  • one of the processes automated by robotic process automation involves configuration of a product for a set of local requirements. In embodiments, one of the processes automated by robotic process automation involves configuration of a set of products for compatibility. In embodiments, one of the processes automated by robotic process automation involves configuration of a request for proposals.
  • one of the processes automated by robotic process automation involves ordering of equipment for a warehouse. In embodiments, one of the processes automated by robotic process automation involves ordering of equipment for a fulfillment center. In embodiments, one of the processes automated by robotic process automation involves classification of a product defect in an image. In embodiments, one of the processes automated by robotic process automation involves inspection of a product in an image.
  • one of the processes automated by robotic process automation involves inspection of product quality data from a set of sensors. In embodiments, one of the processes automated by robotic process automation involves inspection of data from a set of onboard diagnostics on a product. In embodiments, one of the processes automated by robotic process automation involves inspection of diagnostic data from an Internet of Things system. In embodiments, one of the processes automated by robotic process automation involves review of sensor data from environmental sensors in a set of supply chain environments.
  • one of the processes automated by robotic process automation involves selection of inputs for a digital twin. In embodiments, one of the processes automated by robotic process automation involves selection of outputs from a digital twin. In embodiments, one of the processes automated by robotic process automation involves selection of visual elements for presentation in a digital twin. In embodiments, one of the processes automated by robotic process automation involves diagnosis of sources of delay in a supply chain. In embodiments, one of the processes automated by robotic process automation involves diagnosis of sources of scarcity in a supply chain. In embodiments, one of the processes automated by robotic process automation involves diagnosis of sources of congestion in a supply chain.
  • one of the processes automated by robotic process automation involves diagnosis of sources of cost overruns in a supply chain. In embodiments, one of the processes automated by robotic process automation involves diagnosis of sources of product defects in a supply chain. In embodiments, one of the processes automated by robotic process automation involves prediction of maintenance requirements in supply chain infrastructure.
  • the set of demand management applications, supply chain applications, intelligent product applications and enterprise resource management applications may include, for example, ones involving supply chain, asset management, risk management, inventory management, demand management, demand prediction, demand aggregation, pricing, positioning, placement, promotion, blockchain, smart contract, infrastructure management, facility management, analytics, finance, trading, tax, regulatory, identity management, commerce, ecommerce, payments, security, safety, vendor management, process management, compatibility testing, compatibility management, infrastructure testing, incident management, predictive maintenance, logistics, monitoring, remote control, automation, self-configuration, self-healing, self-organization, logistics, reverse logistics, waste reduction, augmented reality, virtual reality, mixed reality, demand customer profiling, entity profiling, enterprise profiling, worker profiling, workforce profiling, component supply policy management, product design, product configuration, product updating, product maintenance, product support, product testing, warehousing, distribution, fulfillment, kit configuration, kit deployment, kit support, kit updating, kit maintenance, kit modification, kit management, shipping fleet management, vehicle fleet management, workforce management, maritime fleet management
  • a set of opportunity miners 1460 may be provided as part of the adaptive intelligence layer 614 , which may be configured to seek and recommend opportunities to improve one or more of the elements of the platform 604 , such as via addition of artificial intelligence 1160 , automation (including robotic process automation 1442 ), or the like to one or more of the systems, sub-systems, components, applications or the like of the VCNP 102 or with which the VCNP 102 interacts.
  • the opportunity miners 1460 may be configured or used by developers of AI or RPA solutions to find opportunities for better solutions and to optimize existing solutions in a value chain network 668 .
  • the opportunity miners 1460 may include a set of systems that collect information within the VCNP 102 and collect information within, about and for a set of value chain network entities 652 and environments, where the collected information has the potential to help identify and prioritize opportunities for increased automation and/or intelligence about the value chain network 668 , about applications 630 , about value chain network entities 652 , or about the VCNP 102 itself.
  • the opportunity miners 1460 may include systems that observe clusters of value chain network workers by time, by type, and by location, such as using cameras, wearables, or other sensors, such as to identify labor-intensive areas and processes in a set of value chain network 668 environments.
  • analytics 838 may be used to identify which environments or activities would most benefit from automation for purposes of improved delivery times, mitigation of congestion, and other performance improvements.
  • opportunity mining may include facilities for solicitation of appropriate training data sets that may be used to facilitate process automation. For example, certain kinds of inputs, if available, would provide very high value for automation, such as video data sets that capture very experienced and/or highly expert workers performing complex tasks.
  • Opportunity miners 1460 may search for such video data sets as described herein; however, in the absence of success (or to supplement available data), the platform may include systems by which a user, such as a developer, may specify a desired type of data, such as software interaction data (such as of an expert working with a program to perform a particular task), video data (such as video showing a set of experts performing a certain kind of delivery process, packing process, picking process, a container movement process, or the like), and/or physical process observation data (such as video, sensor data, or the like).
  • the resulting library of interactions captured in response to specification may be captured as a data set in the data storage layer 624 , such as for consumption by various applications 630 , adaptive intelligence systems 614 , and other processes and systems.
  • the library may include videos that are specifically developed as instructional videos, such as to facilitate developing an automation map that can follow instructions in the video, such as providing a sequence of steps according to a procedure or protocol, breaking down the procedure or protocol into sub-steps that are candidates for automation, and the like.
  • videos may be processed by natural language processing, such as to automatically develop a sequence of labeled instructions that can be used by a developer to facilitate a map, a graph, or other models of a process that assists with development of automation for the process.
  • a specified set of training data sets may be configured to operate as inputs to learning.
  • the training data may be time-synchronized with other data within the platform 604 , such as outputs and outcomes from applications 630 , outputs and outcomes of value chain entities 652 , or the like, so that a given video of a process can be associated with those outputs and outcomes, thereby enabling feedback on learning that is sensitive to the outcomes that occurred when a given process that was captured (such as on video, or through observation of software interactions or physical process interactions).
  • this may relate to an instruction video such as a video of a person who may be building or rebuilding (e.g., rebuilding a bearing set).
  • This instruction video may include individual steps for rebuild that may allow a staging of the training to provide instructions such as parsing the video into stages that mimic the experts staging in the video.
  • this may include tagging of the video to include references to each stage and status (e.g., stage one complete, stage two, etc.)
  • This type of example may utilize artificial intelligence that may understand that there may be a series of sub-functions that add up to a final function.
  • opportunity miners 1460 may include methods, systems, processes, components, services and other elements for mining for opportunities for smart contract definition, formation, configuration and execution.
  • Data collected within the platform 604 such as any data handled by the data handling layers 608 , stored by the data storage layer 624 , collected by the monitoring layer 614 and collection systems 640 , collected about or from entities 652 or obtained from external sources may be used to recognize beneficial opportunities for application or configuration of smart contracts.
  • pricing information about an entity 652 may be used to recognize situations in which the same item or items is disparately priced (in a spot market, futures market, or the like), and the opportunity miner 1460 may provide an alert indicating an opportunity for smart contract formation, such as a contract to buy in one environment at a price below a given threshold and sell in another environment at a price above a given threshold, or vice versa.
  • the adaptive intelligent systems 614 may include value translators 1470 .
  • the value translators 1470 may relate to demand side of transactions. Specifically, for example, the value translators 1470 may understand negative currencies of two marketplaces and may be able to translate value currencies into other currencies (e.g., not only fiat currencies that already have clear translation functions).
  • value translators 1470 may be associated with points of a point-based system (e.g., in a cost-based routing system).
  • value translators 1470 may be loyalty points offered that may be convertible into airline seats and/or may translate to refund policies for staying in a hotel room.
  • value translators 1470 may be used with network prioritization or cost-based routing that happens in networks off of priorities where the point system in these cost-based routing systems is not monetary-based.
  • FIG. 28 additional details of an embodiment of the platform 604 are provided, in particular relating to an overall architecture for the platform 604 .
  • These may include, for the cloud-based management platform 604 , employing a micro-services architecture, a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 614 , a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture; a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities; and a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use.
  • Also provided herein are methods, systems, components and other elements for an information technology system may include: a cloud-based management platform with a micro-services architecture, the platform having: a set of interfaces for accessing and configuring features of the platform; a set of network connectivity facilities for enabling a set of value chain network entities to connect to the platform; a set of adaptive intelligence facilities for automating a set of capabilities of the platform; a set of data storage facilities for storing data collected and handled by the platform; and a set of monitoring facilities for monitoring the value chain network entities; wherein the platform hosts a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin of a product of the enterprise to a point of customer use.
  • FIG. 29 additional details of an embodiment of the platform 604 are provided, in particular relating to an overall architecture for the platform 604 .
  • These may include, for the cloud-based management platform 604 , employing a micro-services architecture, a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 614 , a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • the set of interfaces 702 may include a demand management interface 1402 and a supply chain management interface 1404 .
  • the set of network connectivity facilities 642 for enabling a set of value chain network entities 652 to connect to the platform 604 may include a 5G network system 1410 , such as one that is deployed in a supply chain infrastructure facility operated by the enterprise.
  • the set of network connectivity facilities 642 for enabling a set of value chain network entities 652 to connect to the platform 604 may include an Internet of Things system 1172 , such as one that is deployed in a supply chain infrastructure facility operated by the enterprise, in, on or near a value chain network entity 652 , in a network system, and/or in a cloud computing environment (such as where data collection systems 640 are configured to collect and organize IoT data).
  • an Internet of Things system 1172 such as one that is deployed in a supply chain infrastructure facility operated by the enterprise, in, on or near a value chain network entity 652 , in a network system, and/or in a cloud computing environment (such as where data collection systems 640 are configured to collect and organize IoT data).
  • the set of network connectivity facilities 642 for enabling a set of value chain network entities 652 to connect to the VCNP 102 may include a cognitive networking system 1420 deployed in a supply chain infrastructure facility operated by the enterprise.
  • the set of network connectivity facilities 642 for enabling a set of value chain network entities 652 to connect to the VCNP 102 may include a peer-to-peer network system 1430 , such as one that is deployed in a supply chain infrastructure facility operated by the enterprise.
  • the set of adaptive intelligence facilities or adaptive intelligent systems 614 for automating a set of capabilities of the platform 604 may include an edge intelligence system 1420 , such as one that is deployed in a supply chain infrastructure facility operated by the enterprise.
  • the set of adaptive intelligence facilities or adaptive intelligent systems 614 for automating a set of capabilities of the platform 604 may include a robotic process automation system 1442 .
  • the set of adaptive intelligence facilities or adaptive intelligent systems 614 for automating a set of capabilities of the platform 604 may include or may integrate with a self-configuring data collection system 1440 , such as one that deployed in a supply chain infrastructure facility operated by the enterprise, one that is deployed in a network, and/or one that is deployed in a cloud computing environment. This may include elements of the data collection systems 640 of the data handling layers 608 that interact with or integrate with elements of the adaptive intelligent systems 614 .
  • the set of adaptive intelligence facilities or adaptive intelligent systems 614 for automating a set of capabilities of the platform 604 may include a digital twin system 1700 , such as one representing attributes of a set of value chain network entities, such as the ones controlled by an enterprise.
  • the set of adaptive intelligence facilities or adaptive intelligent systems 614 for automating a set of capabilities of the platform 604 may include a smart contract system 848 , such as one for automating a set of interactions or transactions among a set of value chain network entities 652 based on status data, event data, or other data handled by the data handling layers 608 .
  • the set of data storage facilities or data storage systems 624 for storing data collected and handled by the platform 604 uses a distributed data architecture 1122 .
  • the set of data storage facilities for storing data collected and handled by the platform uses a blockchain 844 .
  • the set of data storage facilities for storing data collected and handled by the platform uses a distributed ledger 1452 .
  • the set of data storage facilities for storing data collected and handled by the platform uses graph database 1124 representing a set of hierarchical relationships of value chain network entities.
  • the set of monitoring facilities 614 for monitoring the value chain network entities 652 includes an Internet of Things monitoring system 1172 , such as for collecting data from IoT systems and devices deployed throughout a value chain network.
  • the set of monitoring facilities 614 for monitoring the value chain network entities 652 includes a set of sensor systems 1462 , such as ones deployed in a value chain environment or in, one or near a value chain network entity 652 , such as in or on a product 1510 .
  • the set of applications 614 includes a set of applications, which may include a variety of types from among, for example, a set of supply chain management applications 21004 , demand management applications 1502 , intelligent product applications 1510 and enterprise resource management applications 1520 .
  • the set of applications includes an asset management application 1530 .
  • the value chain network entities 652 as mentioned throughout this disclosure may include, for example, without limitation, products, suppliers, producers, manufacturers, retailers, businesses, owners, operators, operating facilities, customers, consumers, workers, mobile devices, wearable devices, distributors, resellers, supply chain infrastructure facilities, supply chain processes, logistics processes, reverse logistics processes, demand prediction processes, demand management processes, demand aggregation processes, machines, ships, barges, warehouses, maritime ports, airports, airways, waterways, roadways, railways, bridges, tunnels, online retailers, ecommerce sites, demand factors, supply factors, delivery systems, floating assets, points of origin, points of destination, points of storage, points of use, networks, information technology systems, software platforms, distribution centers, fulfillment centers, containers, container handling facilities, customs, export control, border control, drones, robots, autonomous vehicles, hauling facilities, drones/robots/AVs, waterways, port infrastructure facilities, or others.
  • the platform 604 manages a set of demand factors 1540 , a set of supply factors 1550 and a set of value chain infrastructure facilities 1560 .
  • the supply factors 1550 as mentioned throughout this disclosure may include, for example and without limitation, ones involving component availability, material availability, component location, material location, component pricing, material pricing, taxation, tariff, impost, duty, import regulation, export regulation, border control, trade regulation, customs, navigation, traffic, congestion, vehicle capacity, ship capacity, container capacity, package capacity, vehicle availability, ship availability, container availability, package availability, vehicle location, ship location, container location, port location, port availability, port capacity, storage availability, storage capacity, warehouse availability, warehouse capacity, fulfillment center location, fulfillment center availability, fulfillment center capacity, asset owner identity, system compatibility, worker availability, worker competency, worker location, goods pricing, fuel pricing, energy pricing, route availability, route distance, route cost, route safety, and many others.
  • the demand factors 1540 as mentioned throughout this disclosure may include, for example and without limitation, ones involving product availability, product pricing, delivery timing, need for refill, need for replacement, manufacturer recall, need for upgrade, need for maintenance, need for update, need for repair, need for consumable, taste, preference, inferred need, inferred want, group demand, individual demand, family demand, business demand, need for workflow, need for process, need for procedure, need for treatment, need for improvement, need for diagnosis, compatibility to system, compatibility to product, compatibility to style, compatibility to brand, demographic, psychographic, geolocation, indoor location, destination, route, home location, visit location, workplace location, business location, personality, mood, emotion, customer behavior, business type, business activity, personal activity, wealth, income, purchasing history, shopping history, search history, engagement history, clickstream history, website history, online navigation history, group behavior, family behavior, family membership, customer identity, group identity, business identity, customer profile, business profile, group profile, family profile, declared interest, inferred interest, and many others.
  • the supply chain infrastructure facilities 1560 as mentioned throughout this disclosure may include, for example and without limitation, ship, container ship, boat, barge, maritime port, crane, container, container handling, shipyard, maritime dock, warehouse, distribution, fulfillment, fueling, refueling, nuclear refueling, waste removal, food supply, beverage supply, drone, robot, autonomous vehicle, aircraft, automotive, truck, train, lift, forklift, hauling facilities, conveyor, loading dock, waterway, bridge, tunnel, airport, depot, vehicle station, train station, weigh station, inspection, roadway, railway, highway, customs house, border control, and other facilities.
  • the set of applications 614 as mentioned throughout this disclosure may include, for example and without limitation, supply chain, asset management, risk management, inventory management, demand management, demand prediction, demand aggregation, pricing, positioning, placement, promotion, blockchain, smart contract, infrastructure management, facility management, analytics, finance, trading, tax, regulatory, identity management, commerce, ecommerce, payments, security, safety, vendor management, process management, compatibility testing, compatibility management, infrastructure testing, incident management, predictive maintenance, logistics, monitoring, remote control, automation, self-configuration, self-healing, self-organization, logistics, reverse logistics, waste reduction, augmented reality, virtual reality, mixed reality, demand customer profiling, entity profiling, enterprise profiling, worker profiling, workforce profiling, component supply policy management, product design, product configuration, product updating, product maintenance, product support, product testing, warehousing, distribution, fulfillment, kit configuration, kit deployment, kit support, kit updating, kit maintenance, kit modification, kit management, shipping fleet management, vehicle fleet management, workforce management, maritime fleet management, navigation, routing, shipping management,
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 614 , a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • the platform 604 may include a user interface 1570 that provides a set of unified views for a set of demand management information and supply chain information for a category of goods, such as one that displays status information, event information, activity information, analytics, reporting, or other elements of, relating to, or produced by a set of supply chain management applications 21004 , demand management applications 1502 , intelligent product applications 1510 and enterprise resource management applications 1520 that monitor and/or manage a value chain network and a set of value chain network entities 652 .
  • a user interface 1570 that provides a set of unified views for a set of demand management information and supply chain information for a category of goods, such as one that displays status information, event information, activity information, analytics, reporting, or other elements of, relating to, or produced by a set of supply chain management applications 21004 , demand management applications 1502 , intelligent product applications 1510 and enterprise resource management applications 1520 that monitor and/or manage a value chain network and a set of value chain network entities 652 .
  • the unified view interface 1570 may thus provide, in embodiments, a control tower for an enterprise over a range of assets, such as supply chain infrastructure facilities 1560 and other value chain network entities 652 that are involved as a product 1510 travels from a point of origin through distribution and retail channels to an environment where it is used by a customer. These may include views of demand factors 1540 and supply factors 1550 , so that a user may develop insights about connections among the factors and control one or both of them with coordinated intelligence. Population of a set of unified views may be adapted over time, such as by learning on outcomes 1040 or other operations of the adaptive intelligent systems 614 , such as to determine which views of the interface 1570 provide the most impactful insights, control features, or the like.
  • assets such as supply chain infrastructure facilities 1560 and other value chain network entities 652 that are involved as a product 1510 travels from a point of origin through distribution and retail channels to an environment where it is used by a customer.
  • These may include views of demand factors 1540 and supply factors 1550 , so that
  • the user interface includes a voice operated assistant 1580 .
  • the user interface includes a set of digital twins 1700 for presenting a visual representation of a set of attributes of a set of value chain network entities 652 .
  • the user interface 1570 may include capabilities for configuring the adaptive intelligent systems 614 or adaptive intelligence facilities, such as to allow user selection of attributes, parameters, data sources, inputs to learning, feedback to learning, views, formats, arrangements, or other elements.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a user interface that provides a set of unified views for a set of demand management information and supply chain information for a category of goods.
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 614 , a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • the platform 604 may include a unified database 1590 that supports a set of applications of multiple types, such as ones among a set of supply chain management applications 21004 , demand management applications 1502 , intelligent product applications 1510 and enterprise resource management applications 1520 that monitor and/or manage a value chain network and a set of value chain network entities 652 .
  • the unified database 1590 may thus provide, in embodiments, unification of data storage, access and handling for an enterprise over a range of assets, such as supply chain infrastructure facilities 1560 and other value chain network entities 652 that are involved as a product 1510 travels from a point of origin through distribution and retail channels to an environment where it is used by a customer.
  • This unification may provide a number of advantages, including reduced need for data entry, consistency across applications 630 , reduced latency (and better real-time reporting), reduced need for data transformation and integration, and others. These may include data relating to demand factors 1540 and supply factors 1550 , so that an application 630 may benefit from information collected by, processed, or produced by other applications 630 of the platform 604 and a user can develop insights about connections among the factors and control one or both of them with coordinated intelligence.
  • Population of the unified database 1590 may be adapted over time, such as by learning on outcomes 1040 or other operations of the adaptive intelligent systems 614 , such as to determine which elements of the database 1590 should be made available to which applications, what data structures provide the most benefit, what data should be stored or cached for immediate retrieval, what data can be discarded versus saved, what data is most beneficial to support adaptive intelligent systems 614 , and for other uses.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a unified database that supports a set of applications of at least two types from among a set of demand management applications, a set of supply chain applications, a set of intelligent product applications and a set of enterprise resource management applications for a category of goods.
  • the unified database that supports a set of demand management applications, a set of supply chain applications, a set of intelligent product applications and a set of enterprise resource management applications for a category of goods is a distributed database.
  • the unified database that supports a set of demand management applications, a set of supply chain applications, a set of intelligent product applications and a set of enterprise resource management applications for a category of goods uses a graph database architecture.
  • the set of demand management applications includes a demand prediction application.
  • the set of demand management applications includes a demand aggregation application.
  • the set of demand management applications includes a demand activation application.
  • the set of supply chain management applications includes a vendor search application. In embodiments, the set of supply chain management applications includes a route configuration application. In embodiments, the set of supply chain management applications includes a logistics scheduling application.
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 1160 , a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • the platform 604 may include a set of unified set of data collection and management systems 640 of the set of monitoring facilities or systems 808 that support a set of applications 614 of various types, including a set of supply chain management applications 21004 , demand management applications 1502 , intelligent product applications 1510 and enterprise resource management applications 1520 that monitor and/or manage a value chain network and a set of value chain network entities 652 .
  • the unified data collection and management systems 640 may thus provide, in embodiments, unification of data monitoring, search, discovery, collection, access and handling for an enterprise or other user over a range of assets, such as supply chain infrastructure facilities 1560 and other value chain network entities 652 that are involved as a product 1510 travels from a point of origin through distribution and retail channels to an environment where it is used by a customer.
  • This unification may provide a number of advantages, including reduced need for data entry, consistency across applications 630 , reduced latency (and better real-time reporting), reduced need for data transformation and integration, and others.
  • the unified data collection and management systems 640 may be adapted over time, such as by learning on outcomes 1040 or other operations of the adaptive intelligent systems 614 , such as to determine which elements of the data collection and management systems 640 should be made available to which applications 630 , what data types or sources provide the most benefit, what data should be stored or cached for immediate retrieval, what data can be discarded versus saved, what data is most beneficial to support adaptive intelligent systems 614 , and for other uses.
  • the unified data collection and management systems 640 may use a unified data schema which relates data collection and management for various applications. This may be a single point of truth database at the most tightly bound or a set of distributed data systems that may follow a schema that may be sufficiently common enough that a wide variety of applications may consume the same data as received. For example, sensor data may be pulled from a smart product that may be consumed by a logistics application, a financial application, a demand prediction application, or a genetic programming artificial intelligence (AI) application to change the product, and the like. All of these applications may consume data from a data framework.
  • AI genetic programming artificial intelligence
  • this may occur from blockchains that may contain a distributed ledger or transactional data for purchase and sales or blockchains where there may be an indication of whether or not events had occurred.
  • this data flow may occur through distributed databases, relational databases, graph databases of all types, and the like that may be part of the unified data collection and management systems 640 .
  • the unified data collection and management systems 640 may utilize memory that may be dedicated memory on an asset, in a tag or part of a memory structure of the device itself that may come from a robust pipeline tied to the value chain network entities.
  • the unified data collection and management systems 640 may use classic data integration capabilities that may include adapting protocols such that they can ultimately get to the unified system or schema.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a unified set of data collection systems that support a set of applications of at least two types from among a set of demand management applications, a set of supply chain applications, a set of intelligent product applications and a set of enterprise resource management applications for a category of goods.
  • the unified set of data collection systems includes a set of crowdsourcing data collection systems. In embodiments, the unified set of data collection systems includes a set of Internet of Things data collection systems. In embodiments, the unified set of data collection systems includes a set of self-configuring sensor systems. In embodiments, the unified set of data collection systems includes a set of data collection systems that interact with a network-connected product.
  • the unified set of data collection systems includes a set of mobile data collectors deployed in a set of value chain network environments operated by an enterprise. In embodiments, the unified set of data collection systems includes a set of edge intelligence systems deployed in set of value chain network environments operated by an enterprise. In embodiments, the unified set of data collection systems includes a set of crowdsourcing data collection systems. In embodiments, the unified set of data collection systems includes a set of Internet of Things data collection systems. In embodiments, the unified set of data collection systems includes a set of self-configuring sensor systems. In embodiments, the unified set of data collection systems includes a set of data collection systems that interact with a network-connected product.
  • the unified set of data collection systems includes a set of mobile data collectors deployed in a set of value chain network environments operated by an enterprise. In embodiments, the unified set of data collection systems includes a set of edge intelligence systems deployed in a set of value chain network environments operated by an enterprise.
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 1160 , a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • the platform 604 may include a unified set of Internet of Things systems 1172 that provide coordinated monitoring of various value chain entities 652 in service of a set of multiple applications 630 of various types, such as a set of supply chain management applications 21004 , demand management applications 1502 , intelligent product applications 1510 and enterprise resource management applications 1520 that monitor and/or manage a value chain network and a set of value chain network entities 652 .
  • the unified set of Internet of Things systems 1172 may thus provide, in embodiments, unification of monitoring of, and communication with, a wide range of facilities, devices, systems, environments, and assets, such as supply chain infrastructure facilities 1560 and other value chain network entities 652 that are involved as a product 1510 travels from a point of origin through distribution and retail channels to an environment where it is used by a customer.
  • This unification may provide a number of advantages, including reduced need for data entry, consistency across applications 630 , reduced latency, real-time reporting and awareness, reduced need for data transformation and integration, and others.
  • These may include Internet of Things systems 1172 that are used in connection with demand factors 1540 and supply factors 1550 , so that an application 630 may benefit from information collected by, processed, or produced by the unified set of Internet of Things systems 1172 for other applications 630 of the platform 604 , and a user can develop insights about connections among the factors and control one or both of them with coordinated intelligence.
  • the unified set of Internet of Things systems 1172 may be adapted over time, such as by learning on outcomes 1040 or other operations of the adaptive intelligent systems 614 , such as to determine which elements of the unified set of Internet of Things systems 1172 should be made available to which applications 630 , what IoT systems 1172 provide the most benefit, what data should be stored or cached for immediate retrieval, what data can be discarded versus saved, what data is most beneficial to support adaptive intelligent systems 614 , and for other uses.
  • the unified set of Internet of Things (IoT) systems 1172 may be IoT devices that may be installed in various environments.
  • One goal of the unified set of Internet of Things systems 1172 may be coordination across a city or town involving citywide deployments where collectively a set of IOT devices may be connected by wide area network protocols (e.g., longer range protocols).
  • the unified set of Internet of Things systems 1172 may involve connecting a mesh of devices across several different distribution facilities.
  • the IoT devices may identify collection for each warehouse and the warehouses may use the IoT devices to communicate with each other.
  • the IoT devices may be configured to process data without using the cloud.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications integrated with the platform for enabling an enterprise user of the platform to manage a set of value chain network entities from a point of origin to a point of customer use; and a unified set of Internet of Things systems that provide coordinated monitoring of a set of applications of at least two types from among a set of demand management applications, a set of supply chain applications, a set of intelligent product applications and a set of enterprise resource management applications for a category of goods.
  • the unified set of Internet of Things systems includes a set of smart home Internet of Things devices to enable monitoring of a set of demand factors and a set of Internet of Things devices deployed in proximity to a set of supply chain infrastructure facilities to enable monitoring of a set of supply factors.
  • the unified set of Internet of Things systems includes a set of workplace Internet of Things devices to enable monitoring of a set of demand factors for a set of business customers and a set of Internet of Things devices deployed in proximity to a set of supply chain infrastructure facilities to enable monitoring of a set of supply factors.
  • the unified set of Internet of Things systems includes a set of Internet of Things devices to monitor a set of consumer goods stores to enable monitoring of a set of demand factors for a set of consumers and a set of Internet of Things devices deployed in proximity to a set of supply chain infrastructure facilities to enable monitoring of a set of supply factors.
  • the Internet of Things systems may include, for example and without limitations, camera systems, lighting systems, motion sensing systems, weighing systems, inspection systems, machine vision systems, environmental sensor systems, onboard sensor systems, onboard diagnostic systems, environmental control systems, sensor-enabled network switching and routing systems, RF sensing systems, magnetic sensing systems, pressure monitoring systems, vibration monitoring systems, temperature monitoring systems, heat flow monitoring systems, biological measurement systems, chemical measurement systems, ultrasonic monitoring systems, radiography systems, LIDAR-based monitoring systems, access control systems, penetrating wave sensing systems, SONAR-based monitoring systems, radar-based monitoring systems, computed tomography systems, magnetic resonance imaging systems, network monitoring systems, and many others.
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 1160 , a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • the platform 604 may include a machine vision system 1600 and a digital twin system 1700 , wherein the machine vision system 1600 feeds data to the digital twin system 1700 (which may be enabled by a set of adaptive intelligent systems 614 , including artificial intelligence 1160 , and may be used as interfaces or components of interfaces 702 , such as ones by which an operator may monitor twins 1700 of various value chain network entities 652 ).
  • the machine vision system 1600 and digital twin system 1700 may operate in coordination for a set of multiple applications 630 of various types, such as a set of supply chain management applications 21004 , demand management applications 1502 , intelligent product applications 1510 and enterprise resource management applications 1520 that monitor and/or manage a value chain network and a set of value chain network entities 652 .
  • the machine vision system 1600 and digital twin system 1700 may thus provide, in embodiments, image-based monitoring (with automated processing of image data) a wide range of facilities, devices, systems, environments, and assets, such as supply chain infrastructure facilities 1560 and other value chain network entities 652 that are involved as a product 1510 travels from a point of origin through distribution and retail channels to an environment where it is used by a customer, as well as representation of images, as well as extracted data from images, in a digital twin 1700 .
  • This unification may provide a number of advantages, including improved monitoring, improved visualization and insight, improved visibility, and others.
  • machine vision systems 1600 and digital twin systems 1700 may include machine vision systems 1600 and digital twin systems 1700 that are used in connection with demand factors 1540 and supply factors 1550 , so that an application 630 may benefit from information collected by, processed, or produced by the machine vision system 1600 and digital twin system 1700 for other applications 630 of the platform 604 , and a user can develop insights about connections among the factors and control one or both of them with coordinated intelligence.
  • the machine vision system 1600 and/or digital twin system 1700 may be adapted over time, such as by learning on outcomes 1040 or other operations of the adaptive intelligent systems 614 , such as to determine which elements collected and/or processed by the machine vision system 1600 and/or digital twin system 1700 should be made available to which applications 630 , what elements and/or content provide the most benefit, what data should be stored or cached for immediate retrieval, what data can be discarded versus saved, what data is most beneficial to support adaptive intelligent systems 614 , and for other uses.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and for a set of applications of at least two types from among a set of supply chain applications, a set of demand management applications, a set of intelligent product applications and a set of enterprise resource management applications and having a machine vision system and a digital twin system, wherein the machine vision system feeds data to the digital twin system.
  • the set of supply chain applications and demand management applications is among any described throughout this disclosure or in the documents incorporated by reference herein.
  • the set of supply chain applications and demand management applications includes, for example and without limitation one or more involving inventory management, demand prediction, demand aggregation, pricing, blockchain, smart contract, positioning, placement, promotion, analytics, finance, trading, arbitrage, customer identity management, store planning, shelf-planning, customer route planning, customer route analytics, commerce, ecommerce, payments, customer relationship management, sales, marketing, advertising, bidding, customer monitoring, customer process monitoring, customer relationship monitoring, collaborative filtering, customer profiling, customer feedback, similarity analytics, customer clustering, product clustering, seasonality factor analytics, customer behavior tracking, customer behavior analytics, product design, product configuration, A/B testing, product variation analytics, augmented reality, virtual reality, mixed reality, customer demand profiling, customer mood, emotion or affect detection, customer mood, emotion of affect analytics, business entity profiling, customer enterprise profiling, demand matching, location-based targeting, location-based offering, point of sale interface, point of use interface, search, advertisement, entity discovery, entity search, enterprise resource planning, workforce management, customer digital twin, product pricing, product bundling
  • the set of supply chain applications and demand management applications may include, without limitation, one or more of supply chain, asset management, risk management, inventory management, blockchain, smart contract, infrastructure management, facility management, analytics, finance, trading, tax, regulatory, identity management, commerce, ecommerce, payments, security, safety, vendor management, process management, compatibility testing, compatibility management, infrastructure testing, incident management, predictive maintenance, logistics, monitoring, remote control, automation, self-configuration, self-healing, self-organization, logistics, reverse logistics, waste reduction, augmented reality, virtual reality, mixed reality, supply chain digital twin, vendor profiling, supplier profiling, manufacturer profiling, logistics entity profiling, enterprise profiling, worker profiling, workforce profiling, component supply policy management, warehousing, distribution, fulfillment, shipping fleet management, vehicle fleet management, workforce management, maritime fleet management, navigation, routing, shipping management, opportunity matching, search, entity discovery, entity search, distribution, delivery, enterprise resource planning or other applications.
  • the set of supply chain applications and demand management applications may include, without limitation, one or more of asset management, risk management, inventory management, blockchain, smart contract, analytics, finance, trading, tax, regulatory, identity management, commerce, ecommerce, payments, security, safety, compatibility testing, compatibility management, incident management, predictive maintenance, monitoring, remote control, automation, self-configuration, self-healing, self-organization, waste reduction, augmented reality, virtual reality, mixed reality, product design, product configuration, product updating, product maintenance, product support, product testing, kit configuration, kit deployment, kit support, kit updating, kit maintenance, kit modification, kit management, product digital twin, opportunity matching, search, advertisement, entity discovery, entity search, variation, simulation, user interface, application programming interface, connectivity management, natural language interface, voice/speech interface, robotic interface, touch interface, haptic interface, vision system interface, enterprise resource planning, or other applications.
  • the set of supply chain applications and demand management applications may include, without limitation, one or more of operations, finance, asset management, supply chain management, demand management, human resource management, product management, risk management, regulatory and compliance management, inventory management, infrastructure management, facilities management, analytics, trading, tax, identity management, vendor management, process management, project management, operations management, customer relationship management, workforce management, incident management, research and development, sales management, marketing management, fleet management, opportunity analytics, decision support, strategic planning, forecasting, resource management, property management, or other applications.
  • the machine vision system includes an artificial intelligence system that is trained to recognize a type of value chain asset based on a labeled data set of images of such type of value chain assets.
  • the digital twin presents an indicator of the type of asset based on the output of the artificial intelligence system.
  • the machine vision system includes an artificial intelligence system that is trained to recognize a type of activity involving a set of value chain entities based on a labeled data set of images of such type of activity.
  • the digital twin presents an indicator of the type of activity based on the output of the artificial intelligence system.
  • the machine vision system includes an artificial intelligence system that is trained to recognize a safety hazard involving a value chain entity based on a training data set that includes a set of images of value chain network activities and a set of value chain network safety outcomes.
  • the digital twin presents an indicator of the hazard based on the output of the artificial intelligence system.
  • the machine vision system includes an artificial intelligence system that is trained to predict a delay based on a training data set that includes a set of images of value chain network activities and a set of value chain network timing outcomes.
  • the digital twin presents an indicator of a likelihood of delay based on the output of the artificial intelligence system.
  • artificial intelligence in connection with value chain network entities 652 and related processes and applications may be used to facilitate, among other things: (a) the optimization, automation and/or control of various functions, workflows, applications, features, resource utilization and other factors, (b) recognition or diagnosis of various states, entities, patterns, events, contexts, behaviors, or other elements; and/or (c) the forecasting of various states, events, contexts or other factors.
  • artificial intelligence improves, a large array of domain-specific and/or general artificial intelligence systems have become available and are likely to continue to proliferate.
  • an artificial intelligence store 3504 that is configured to enable collection, organization, recommendation and presentation of relevant sets of artificial intelligence systems based on one or more attributes of a domain and/or a domain-related problem.
  • an artificial intelligence store 3504 may include a set of interfaces to artificial intelligence systems, such as enabling the download of relevant artificial intelligence applications, establishment of links or other connections to artificial intelligence systems (such as links to cloud-deployed artificial intelligence systems via APIs, ports, connectors, or other interfaces) and the like.
  • the artificial intelligence store 3504 may include descriptive content with respect to each of a variety of artificial intelligence systems, such as metadata or other descriptive material indicating suitability of a system for solving particular types of problems (e.g., forecasting, NLP, image recognition, pattern recognition, motion detection, route optimization, or many others) and/or for operating on domain-specific inputs, data or other entities.
  • the artificial intelligence store 3504 may be organized by category, such as domain, input types, processing types, output types, computational requirements and capabilities, cost, energy usage, and other factors.
  • an interface to the application store 3504 may take input from a developer and/or from the platform (such as from an opportunity miner 1460 ) that indicates one or more attributes of a problem that may be addressed through artificial intelligence and may provide a set of recommendations, such as via an artificial intelligence attribute search engine, for a subset of artificial intelligence solutions that may represent favorable candidates based on the developer's domain-specific problem.
  • Search results or recommendations may, in embodiments, be based at least in part on collaborative filtering, such as by asking developers to indicate or select elements of favorable models, as well as by clustering, such as by using similarity matrices, k-means clustering, or other clustering techniques that associate similar developers, similar domain-specific problems, and/or similar artificial intelligence solutions.
  • the artificial intelligence store 3504 may include e-commerce features, such as ratings, reviews, links to relevant content, and mechanisms for provisioning, licensing, delivery and payment (including allocation of payments to affiliates and or contributors), including ones that operate using smart contract and/or blockchain features to automate purchasing, licensing, payment tracking, settlement of transactions, or other features.
  • e-commerce features such as ratings, reviews, links to relevant content, and mechanisms for provisioning, licensing, delivery and payment (including allocation of payments to affiliates and or contributors), including ones that operate using smart contract and/or blockchain features to automate purchasing, licensing, payment tracking, settlement of transactions, or other features.
  • the artificial intelligence system 1160 may define a machine learning model 3000 for performing analytics, simulation, decision making, and prediction making related to data processing, data analysis, simulation creation, and simulation analysis of one or more of the value chain entities 652 .
  • the machine learning model 3000 is an algorithm and/or statistical model that performs specific tasks without using explicit instructions, relying instead on patterns and inference.
  • the machine learning model 3000 builds one or more mathematical models based on training data to make predictions and/or decisions without being explicitly programmed to perform the specific tasks.
  • the machine learning model 3000 may receive inputs of sensor data as training data, including event data 1034 and state data 1140 related to one or more of the value chain entities 652 .
  • the sensor data input to the machine learning model 3000 may be used to train the machine learning model 3000 to perform the analytics, simulation, decision making, and prediction making relating to the data processing, data analysis, simulation creation, and simulation analysis of the one or more of the value chain entities 652 .
  • the machine learning model 3000 may also use input data from a user or users of the information technology system.
  • the machine learning model 3000 may include an artificial neural network, a decision tree, a support vector machine, a Bayesian network, a genetic algorithm, any other suitable form of machine learning model, or a combination thereof.
  • the machine learning model 3000 may be configured to learn through supervised learning, unsupervised learning, reinforcement learning, self-learning, feature learning, sparse dictionary learning, anomaly detection, association rules, a combination thereof, or any other suitable algorithm for learning.
  • the artificial intelligence system 1160 may also define the digital twin system 1700 to create a digital replica of one or more of the value chain entities 652 .
  • the digital replica of the one or more of the value chain entities 652 may use substantially real-time sensor data to provide for substantially real-time virtual representation of the value chain entity 652 and provides for simulation of one or more possible future states of the one or more value chain entities 652 .
  • the digital replica exists simultaneously with the one or more value chain entities 652 being replicated.
  • the digital replica provides one or more simulations of both physical elements and properties of the one or more value chain entities 652 being replicated and the dynamics thereof, in embodiments, throughout the lifestyle of the one or more value chain entities 652 being replicated.
  • the digital replica may provide a hypothetical simulation of the one or more value chain entities 652 , for example during a design phase before the one or more value chain entities are constructed or fabricated, or during or after construction or fabrication of the one or more value chain entities by allowing for hypothetical extrapolation of sensor data to simulate a state of the one or more value chain entities 652 , such as during high stress, after a period of time has passed during which component wear may be an issue, during maximum throughput operation, after one or more hypothetical or planned improvements have been made to the one or more value chain entities 652 , or any other suitable hypothetical situation.
  • the machine learning model 3000 may automatically predict hypothetical situations for simulation with the digital replica, such as by predicting possible improvements to the one or more value chain entities 652 , predicting when one or more components of the one or more value chain entities 652 may fail, and/or suggesting possible improvements to the one or more value chain entities 652 , such as changes to timing settings, arrangement, components, or any other suitable change to the value chain entities 652 .
  • the digital replica allows for simulation of the one or more value chain entities 652 during both design and operation phases of the one or more value chain entities 652 , as well as simulation of hypothetical operation conditions and configurations of the one or more value chain entities 652 .
  • the digital replica allows for invaluable analysis and simulation of the one or more value chain entities, by facilitating observation and measurement of nearly any type of metric, including temperature, wear, light, vibration, etc. not only in, on, and around each component of the one or more value chain entities 652 , but in some embodiments within the one or more value chain entities 652 .
  • the machine learning model 3000 may process the sensor data including the event data 1034 and the state data 1140 to define simulation data for use by the digital twin system 1700 .
  • the machine learning model 3000 may, for example, receive state data 1140 and event data 1034 related to a particular value chain entity 652 of the plurality of value chain entities 652 and perform a series of operations on the state data 1140 and the event data 1034 to format the state data 1140 and the event data 1034 into a format suitable for use by the digital twin system 1700 in creation of a digital replica of the value chain entity 652 .
  • one or more value chain entities 652 may include a robot configured to augment products on an adjacent assembly line.
  • the machine learning model 3000 may collect data from one or more sensors positioned on, near, in, and/or around the robot.
  • the machine learning model 3000 may perform operations on the sensor data to process the sensor data into simulation data and output the simulation data to the digital twin system 1700 .
  • the digital twin simulation 1700 may use the simulation data to create one or more digital replicas of the robot, the simulation including for example metrics including temperature, wear, speed, rotation, and vibration of the robot and components thereof.
  • the simulation may be a substantially real-time simulation, allowing for a human user of the information technology to view the simulation of the robot, metrics related thereto, and metrics related to components thereof, in substantially real time.
  • the simulation may be a predictive or hypothetical situation, allowing for a human user of the information technology to view a predictive or hypothetical simulation of the robot, metrics related thereto, and metrics related to components thereof.
  • the machine learning model 3000 and the digital twin system 1700 may process sensor data and create a digital replica of a set of value chain entities of the plurality of value chain entities 652 to facilitate design, real-time simulation, predictive simulation, and/or hypothetical simulation of a related group of value chain entities.
  • the digital replica of the set of value chain entities may use substantially real-time sensor data to provide for substantially real-time virtual representation of the set of value chain entities and provide for simulation of one or more possible future states of the set of value chain entities.
  • the digital replica exists simultaneously with the set of value chain entities being replicated.
  • the digital replica provides one or more simulations of both physical elements and properties of the set of value chain entities being replicated and the dynamics thereof, in embodiments throughout the lifestyle of the set of value chain entities being replicated.
  • the one or more simulations may include a visual simulation, such as a wire-frame virtual representation of the one or more value chain entities 652 that may be viewable on a monitor, using an augmented reality (AR) apparatus, or using a virtual reality (VR) apparatus.
  • the visual simulation may be able to be manipulated by a human user of the information technology system, such as zooming or highlighting components of the simulation and/or providing an exploded view of the one or more value chain entities 652 .
  • the digital replica may provide a hypothetical simulation of the set of value chain entities, for example during a design phase before the one or more value chain entities are constructed or fabricated, or during or after construction or fabrication of the one or more value chain entities by allowing for hypothetical extrapolation of sensor data to simulate a state of the set of value chain entities, such as during high stress, after a period of time has passed during which component wear may be an issue, during maximum throughput operation, after one or more hypothetical or planned improvements have been made to the set of value chain entities, or any other suitable hypothetical situation.
  • the machine learning model 3000 may automatically predict hypothetical situations for simulation with the digital replica, such as by predicting possible improvements to the set of value chain entities, predicting when one or more components of the set of value chain entities may fail, and/or suggesting possible improvements to the set of value chain entities, such as changes to timing settings, arrangement, components, or any other suitable change to the value chain entities 652 .
  • the digital replica allows for simulation of the set of value chain entities during both design and operation phases of the set of value chain entities, as well as simulation of hypothetical operation conditions and configurations of the set of value chain entities.
  • the digital replica allows for invaluable analysis and simulation of the one or more value chain entities, by facilitating observation and measurement of nearly any type of metric, including temperature, wear, light, vibration, etc.
  • the machine learning model 3000 may process the sensor data including the event data 1034 and the state data 1140 to define simulation data for use by the digital twin system 1700 .
  • the machine learning model 3000 may, for example, receive state data 1140 and event data 1034 related to a particular value chain entity 652 of the plurality of value chain entities 652 and perform a series of operations on the state data 1140 and the event data 1034 to format the state data 1140 and the event data 1034 into a format suitable for use by the digital twin system 1700 in the creation of a digital replica of the set of value chain entities.
  • a set of value chain entities may include a die machine configured to place products on a conveyor belt, the conveyor belt on which the die machine is configured to place the products, and a plurality of robots configured to add parts to the products as they move along the assembly line.
  • the machine learning model 3000 may collect data from one or more sensors positioned on, near, in, and/or around each of the die machines, the conveyor belt, and the plurality of robots. The machine learning model 3000 may perform operations on the sensor data to process the sensor data into simulation data and output the simulation data to the digital twin system 1700 .
  • the digital twin simulation 1700 may use the simulation data to create one or more digital replicas of the die machine, the conveyor belt, and the plurality of robots, the simulation including for example metrics including temperature, wear, speed, rotation, and vibration of the die machine, the conveyor belt, and the plurality of robots and components thereof.
  • the simulation may be a substantially real-time simulation, allowing for a human user of the information technology to view the simulation of the die machine, the conveyor belt, and the plurality of robots, metrics related thereto, and metrics related to components thereof, in substantially real time.
  • the simulation may be a predictive or hypothetical situation, allowing for a human user of the information technology to view a predictive or hypothetical simulation of the die machine, the conveyor belt, and the plurality of robots, metrics related thereto, and metrics related to components thereof.
  • the machine learning model 3000 may prioritize collection of sensor data for use in digital replica simulations of one or more of the value chain entities 652 .
  • the machine learning model 3000 may use sensor data and user inputs to train, thereby learning which types of sensor data are most effective for creation of digital replicate simulations of one or more of the value chain entities 652 .
  • the machine learning model 3000 may find that a particular value chain entity 652 has dynamic properties such as component wear and throughput affected by temperature, humidity, and load.
  • the machine learning model 3000 may, through machine learning, prioritize collection of sensor data related to temperature, humidity, and load, and may prioritize processing sensor data of the prioritized type into simulation data for output to the digital twin system 1700 .
  • the machine learning model 3000 may suggest to a user of the information technology system that more and/or different sensors of the prioritized type be implemented in the information technology and value chain system near and around the value chain entity 652 being simulation such that more and/or better data of the prioritized type may be used in simulation of the value chain entity 652 via the digital replica thereof.
  • the machine learning model 3000 may be configured to learn to determine which types of sensor data are to be processed into simulation data for transmission to the digital twin system 1700 based on one or both of a modeling goal and a quality or type of sensor data.
  • a modeling goal may be an objective set by a user of the information technology system or may be predicted or learned by the machine learning model 3000 .
  • Examples of modeling goals include creating a digital replica capable of showing dynamics of throughput on an assembly line, which may include collection, simulation, and modeling of, e.g., thermal, electrical power, component wear, and other metrics of a conveyor belt, an assembly machine, one or more products, and other components of the value chain.
  • the machine learning model 3000 may be configured to learn to determine which types of sensor data are necessary to be processed into simulation data for transmission to the digital twin system 1700 to achieve such a model.
  • the machine learning model 3000 may analyze which types of sensor data are being collected, the quality and quantity of the sensor data being collected, and what the sensor data being collected represents, and may make decisions, predictions, analyses, and/or determinations related to which types of sensor data are and/or are not relevant to achieving the modeling goal and may make decisions, predictions, analyses, and/or determinations to prioritize, improve, and/or achieve the quality and quantity of sensor data being processed into simulation data for use by the digital twin system 1700 in achieving the modeling goal.
  • a user of the information technology system may input a modeling goal into the machine learning model 3000 .
  • the machine learning model 3000 may learn to analyze training data to output suggestions to the user of the information technology system regarding which types of sensor data are most relevant to achieving the modeling goal, such as one or more types of sensors positioned in, on, or near a value chain entity or a plurality of value chain entities that is relevant to the achievement of the modeling goal is and/or are not sufficient for achieving the modeling goal, and how a different configuration of the types of sensors, such as by adding, removing, or repositioning sensors, may better facilitate achievement of the modeling goal by the machine learning model 3000 and the digital twin system 1700 .
  • the machine learning model 3000 may automatically increase or decrease collection rates, processing, storage, sampling rates, bandwidth allocation, bitrates, and other attributes of sensor data collection to achieve or better achieve the modeling goal. In some embodiments, the machine learning model 3000 may make suggestions or predictions to a user of the information technology system related to increasing or decreasing collection rates, processing, storage, sampling rates, bandwidth allocation, bitrates, and other attributes of sensor data collection to achieve or better achieve the modeling goal. In some embodiments, the machine learning model 3000 may use sensor data, simulation data, previous, current, and/or future digital replica simulations of one or more value chain entities 652 of the plurality of value chain entities 652 to automatically create and/or propose modeling goals.
  • modeling goals automatically created by the machine learning model 3000 may be automatically implemented by the machine learning model 3000 . In some embodiments, modeling goals automatically created by the machine learning model 3000 may be proposed to a user of the information technology system, and implemented only after acceptance and/or partial acceptance by the user, such as after modifications are made to the proposed modeling goal by the user.
  • the user may input the one or more modeling goals, for example, by inputting one or more modeling commands to the information technology system.
  • the one or more modeling commands may include, for example, a command for the machine learning model 3000 and the digital twin system 1700 to create a digital replica simulation of one value chain entity 652 or a set of value chain entities of the plurality of 652 , may include a command for the digital replica simulation to be one or more of a real-time simulation, and a hypothetical simulation.
  • the modeling command may also include, for example, parameters for what types of sensor data should be used, sampling rates for the sensor data, and other parameters for the sensor data used in the one or more digital replica simulations.
  • the machine learning model 3000 may be configured to predict modeling commands, such as by using previous modeling commands as training data.
  • the machine learning model 3000 may propose predicted modeling commands to a user of the information technology system, for example, to facilitate simulation of one or more of the value chain entities 652 that may be useful for the management of the value chain entities 652 and/or to allow the user to easily identify potential issues with or possible improvements to the value chain entities 652 .
  • the machine learning model 3000 may be configured to evaluate a set of hypothetical simulations of one or more of the value chain entities 652 .
  • the set of hypothetical simulations may be created by the machine learning model 3000 and the digital twin system 1700 as a result of one or more modeling commands, as a result of one or more modeling goals, one or more modeling commands, by prediction by the machine learning model 3000 , or a combination thereof.
  • the machine learning model 3000 may evaluate the set of hypothetical simulations based on one or more metrics defined by the user, one or more metrics defined by the machine learning model 3000 , or a combination thereof.
  • the machine learning model 3000 may evaluate each of the hypothetical simulations of the set of hypothetical simulations independently of one another.
  • the machine learning model 3000 may evaluate one or more of the hypothetical simulations of the set of hypothetical simulations in relation to one another, for example by ranking the hypothetical simulations or creating tiers of the hypothetical simulations based on one or more metrics.
  • the machine learning model 3000 may include one or more model interpretability systems to facilitate human understanding of outputs of the machine learning model 3000 , as well as information and insight related to cognition and processes of the machine learning model 3000 , i.e., the one or more model interpretability systems allow for human understanding of not only “what” the machine learning model 3000 is outputting, but also “why” the machine learning model 3000 is outputting the outputs thereof, and what process led to the 3000 formulating the outputs.
  • the one or more model interpretability systems may also be used by a human user to improve and guide training of the machine learning model 3000 , to help debug the machine learning model 3000 , to help recognize bias in the machine learning model 3000 .
  • the one or more model interpretability systems may include one or more of linear regression, logistic regression, a generalized linear model (GLM), a generalized additive model (GAM), a decision tree, a decision rule, RuleFit, Naive Bayes Classifier, a K-nearest neighbors algorithm, a partial dependence plot, individual conditional expectation (ICE), an accumulated local effects (ALE) plot, feature interaction, permutation feature importance, a global surrogate model, a local surrogate (LIME) model, scoped rules, i.e., anchors, Shapley values, Shapley additive explanations (SHAP), feature visualization, network dissection, or any other suitable machine learning interpretability implementation.
  • the one or more model interpretability systems may include a model dataset visualization system.
  • the model dataset visualization system is configured to automatically provide to a human user of the information technology system visual analysis related to distribution of values of the sensor data, the simulation data, and data nodes of the machine learning model 3000 .
  • the machine learning model 3000 may include and/or implement an embedded model interpretability system, such as a Bayesian case model (BCM) or glass box.
  • BCM Bayesian case model
  • the Bayesian case model uses Bayesian case-based reasoning, prototype classification, and clustering to facilitate human understanding of data such as the sensor data, the simulation data, and data nodes of the machine learning model 3000 .
  • the model interpretability system may include and/or implement a glass box interpretability method, such as a Gaussian process, to facilitate human understanding of data such as the sensor data, the simulation data, and data nodes of the machine learning model 3000 .
  • the machine learning model 3000 may include and/or implement testing with concept activation vectors (TCAV).
  • TCAV allows the machine learning model 3000 to learn human-interpretable concepts, such as “running,” “not running,” “powered,” “not powered,” “robot,” “human,” “truck,” or “ship” from examples by a process including defining the concept, determining concept activation vectors, and calculating directional derivatives.
  • human-interpretable concepts, objects, states, etc. may allow the machine learning model 3000 to output useful information related to the value chain entities 652 and data collected therefrom in a format that is readily understood by a human user of the information technology system.
  • the machine learning model 3000 may be and/or include an artificial neural network, e.g., a connectionist system configured to “learn” to perform tasks by considering examples and without being explicitly programmed with task-specific rules.
  • the machine learning model 3000 may be based on a collection of connected units and/or nodes that may act like artificial neurons that may in some ways emulate neurons in a biological brain.
  • the units and/or nodes may each have one or more connections to other units and/or nodes.
  • the units and/or nodes may be configured to transmit information, e.g., one or more signals, to other units and/or nodes, process signals received from other units and/or nodes, and forward processed signals to other units and/or nodes.
  • One or more of the units and/or nodes and connections therebetween may have one or more numerical “weights” assigned.
  • the assigned weights may be configured to facilitate learning, i.e., training, of the machine learning model 3000 .
  • the weights assigned weights may increase and/or decrease one or more signals between one or more units and/or nodes, and in some embodiments may have one or more thresholds associated with one or more of the weights.
  • the one or more thresholds may be configured such that a signal is only sent between one or more units and/or nodes, if a signal and/or aggregate signal crosses the threshold.
  • the units and/or nodes may be assigned to a plurality of layers, each of the layers having one or both of inputs and outputs.
  • a first layer may be configured to receive training data, transform at least a portion of the training data, and transmit signals related to the training data and transformation thereof to a second layer.
  • a final layer may be configured to output an estimate, conclusion, product, or other consequence of processing of one or more inputs by the machine learning model 3000 .
  • Each of the layers may perform one or more types of transformations, and one or more signals may pass through one or more of the layers one or more times.
  • the machine learning model 3000 may employ deep learning and being at least partially modeled and/or configured as a deep neural network, a deep belief network, a recurrent neural network, and/or a convolutional neural network, such as by being configured to include one or more hidden layers.
  • the machine learning model 3000 may be and/or include a decision tree, e.g., a tree-based predictive model configured to identify one or more observations and determine one or more conclusions based on an input.
  • the observations may be modeled as one or more “branches” of the decision tree, and the conclusions may be modeled as one or more “leaves” of the decision tree.
  • the decision tree may be a classification tree.
  • the classification tree may include one or more leaves representing one or more class labels, and one or more branches representing one or more conjunctions of features configured to lead to the class labels.
  • the decision tree may be a regression tree.
  • the regression tree may be configured such that one or more target variables may take continuous values.
  • the machine learning model 3000 may be and/or include a support vector machine, e.g., a set of related supervised learning methods configured for use in one or both of classification and regression-based modeling of data.
  • the support vector machine may be configured to predict whether a new example falls into one or more categories, the one or more categories being configured during training of the support vector machine.
  • the machine learning model 3000 may be configured to perform regression analysis to determine and/or estimate a relationship between one or more inputs and one or more features of the one or more inputs.
  • Regression analysis may include linear regression, wherein the machine learning model 3000 may calculate a single line to best fit input data according to one or more mathematical criteria.
  • inputs to the machine learning model 3000 may be tested, such as by using a set of testing data that is independent from the data set used for the creation and/or training of the machine learning model, such as to test the impact of various inputs to the accuracy of the model 3000 .
  • inputs to the regression model may be removed, including single inputs, pairs of inputs, triplets, and the like, to determine whether the absence of inputs creates a material degradation of the success of the model 3000 . This may assist with recognition of inputs that are in fact correlated (e.g., are linear combinations of the same underlying data), that are overlapping, or the like.
  • Comparison of model success may help select among alternative input data sets that provide similar information, such as to identify the inputs (among several similar ones) that generate the least “noise” in the model, that provide the most impact on model effectiveness for the lowest cost, or the like.
  • input variation and testing of the impact of input variation on model effectiveness may be used to prune or enhance model performance for any of the machine learning systems described throughout this disclosure.
  • the machine learning model 3000 may be and/or include a Bayesian network.
  • the Bayesian network may be a probabilistic graphical model configured to represent a set of random variables and conditional independence of the set of random variables.
  • the Bayesian network may be configured to represent the random variables and conditional independence via a directed acyclic graph.
  • the Bayesian network may include one or both of a dynamic Bayesian network and an influence diagram.
  • the machine learning model 3000 may be defined via supervised learning, i.e., one or more algorithms configured to build a mathematical model of a set of training data containing one or more inputs and desired outputs.
  • the training data may consist of a set of training examples, each of the training examples having one or more inputs and desired outputs, i.e., a supervisory signal.
  • Each of the training examples may be represented in the machine learning model 3000 by an array and/or a vector, i.e., a feature vector.
  • the training data may be represented in the machine learning model 3000 by a matrix.
  • the machine learning model 3000 may learn one or more functions via iterative optimization of an objective function, thereby learning to predict an output associated with new inputs.
  • the objective function may provide the machine learning model 3000 with the ability to accurately determine an output for inputs other than inputs included in the training data.
  • the machine learning model 3000 may be defined via one or more supervised learning algorithms such as active learning, statistical classification, regression analysis, and similarity learning.
  • Active learning may include interactively querying, by the machine learning model AILD102T, a user and/or an information source to label new data points with desired outputs.
  • Statistical classification may include identifying, by the machine learning model 3000 , to which a set of subcategories, i.e., subpopulations, a new observation belongs based on a training set of data containing observations having known categories.
  • Regression analysis may include estimating, by the machine learning model 3000 relationships between a dependent variable, i.e., an outcome variable, and one or more independent variables, i.e., predictors, covariates, and/or features.
  • Similarity learning may include learning, by the machine learning model 3000 , from examples using a similarity function, the similarity function being designed to measure how similar or related two objects are.
  • the machine learning model 3000 may be defined via unsupervised learning, i.e., one or more algorithms configured to build a mathematical model of a set of data containing only inputs by finding structure in the data such as grouping or clustering of data points.
  • the machine learning model 3000 may learn from test data, i.e., training data, that has not been labeled, classified, or categorized.
  • the unsupervised learning algorithm may include identifying, by the machine learning model 3000 , commonalities in the training data and learning by reacting based on the presence or absence of the identified commonalities in new pieces of data.
  • the machine learning model 3000 may generate one or more probability density functions.
  • the machine learning model 3000 may learn by performing cluster analysis, such as by assigning a set of observations into subsets, i.e., clusters, according to one or more predesignated criteria, such as according to a similarity metric of which internal compactness, separation, estimated density, and/or graph connectivity are factors.
  • the machine learning model 3000 may be defined via semi-supervised learning, i.e., one or more algorithms using training data wherein some training examples may be missing training labels.
  • the semi-supervised learning may be weakly supervised learning, wherein the training labels may be noisy, limited, and/or imprecise.
  • the noisy, limited, and/or imprecise training labels may be cheaper and/or less labor intensive to produce, thus allowing the machine learning model 3000 to train on a larger set of training data for less cost and/or labor.
  • the machine learning model 3000 may be defined via reinforcement learning, such as one or more algorithms using dynamic programming techniques such that the machine learning model 3000 may train by taking actions in an environment in order to maximize a cumulative reward.
  • the training data is represented as a Markov Decision Process.
  • the machine learning model 3000 may be defined via self-learning, wherein the machine learning model 3000 is configured to train using training data with no external rewards and no external teaching, such as by employing a Crossbar Adaptive Array (CAA).
  • CAA Crossbar Adaptive Array
  • the CAA may compute decisions about actions and/or emotions about consequence situations in a crossbar fashion, thereby driving teaching of the machine learning model 3000 by interactions between cognition and emotion.
  • the machine learning model 3000 may be defined via feature learning, i.e., one or more algorithms designed to discover increasingly accurate and/or apt representations of one or more inputs provided during training, e.g., training data.
  • Feature learning may include training via principal component analysis and/or cluster analysis.
  • Feature learning algorithms may include attempting, by the machine learning model 3000 , to preserve input training data while also transforming the input training data such that the transformed input training data is useful.
  • the machine learning model 3000 may be configured to transform the input training data prior to performing one or more classifications and/or predictions of the input training data.
  • the machine learning model 3000 may be configured to reconstruct input training data from one or more unknown data-generating distributions without necessarily conforming to implausible configurations of the input training data according to the distributions.
  • the feature learning algorithm may be performed by the machine learning model 3000 in a supervised, unsupervised, or semi-supervised manner.
  • the machine learning model 3000 may be defined via anomaly detection, i.e., by identifying rare and/or outlier instances of one or more items, events and/or observations.
  • the rare and/or outlier instances may be identified by the instances differing significantly from patterns and/or properties of a majority of the training data.
  • Unsupervised anomaly detection may include detecting of anomalies, by the machine learning model 3000 , in an unlabeled training data set under an assumption that a majority of the training data is “normal.”
  • Supervised anomaly detection may include training on a data set wherein at least a portion of the training data has been labeled as “normal” and/or “abnormal.”
  • the machine learning model 3000 may be defined via robot learning.
  • Robot learning may include generation, by the machine learning model 3000 , of one or more curricula, the curricula being sequences of learning experiences, and cumulatively acquiring new skills via exploration guided by the machine learning model 3000 and social interaction with humans by the machine learning model 3000 . Acquisition of new skills may be facilitated by one or more guidance mechanisms such as active learning, maturation, motor synergies, and/or imitation.
  • the machine learning model 3000 can be defined via association rule learning.
  • Association rule learning may include discovering relationships, by the machine learning model 3000 , between variables in databases, in order to identify strong rules using some measure of “interestingness.”
  • Association rule learning may include identifying, learning, and/or evolving rules to store, manipulate and/or apply knowledge.
  • the machine learning model 3000 may be configured to learn by identifying and/or utilizing a set of relational rules, the relational rules collectively representing knowledge captured by the machine learning model 3000 .
  • Association rule learning may include one or more of learning classifier systems, inductive logic programming, and artificial immune systems.
  • Learning classifier systems are algorithms that may combine a discovery component, such as one or more genetic algorithms, with a learning component, such as one or more algorithms for supervised learning, reinforcement learning, or unsupervised learning.
  • Inductive logic programming may include rule-learning, by the machine learning model 3000 , using logic programming to represent one or more of input examples, background knowledge, and hypothesis determined by the machine learning model 3000 during training.
  • the machine learning model 3000 may be configured to derive a hypothesized logic program entailing all positive examples given an encoding of known background knowledge and a set of examples represented as a logical database of facts.
  • another set of solutions which may be deployed alone or in connection with other elements of the platform, including the artificial intelligence store 3504 , may include a set of functional imaging capabilities 3502 , which may comprise monitoring systems 640 and in some cases physical process observation systems 1510 and/or software interaction observation systems 1500 , such as for monitoring various value chain entities 652 .
  • Functional imaging systems 3502 may, in embodiments, provide considerable insight into the types of artificial intelligence that are likely to be most effective in solving particular types of problems most effectively.
  • computational and networking systems as they grow in scale, complexity and interconnections, manifest problems of information overload, noise, network congestion, energy waste, and many others.
  • the human brain operates with a massive neural network organized into interconnected modular systems, each of which has a degree of adaptation to solve particular problems, from regulation of biological systems and maintenance of homeostasis, to detection of a wide range of static and dynamic patterns, to recognition of threats and opportunities, among many others.
  • Functional imaging 3502 such as functional magnetic resonance imaging (fMRI), electroencephalogram (EEG), computed tomography (CT) and other brain imaging systems have improved to the point that patterns of brain activity can be recognized in real time and temporally associated with other information, such behaviors, stimulus information, environmental condition data, gestures, eye movements, and other information, such that via functional imaging, either alone or in combination with other information collected by monitoring systems 808 , the platform may determine and classify what brain modules, operations, systems, and/or functions are employed during the undertaking of a set of tasks or activities, such as ones involving software interaction 1500 , physical process observations 1510 , or a combination thereof.
  • fMRI functional magnetic resonance imaging
  • EEG electroencephalogram
  • CT computed tomography
  • This classification may assist in selection and/or configuration of a set of artificial intelligence solutions, such as from an artificial intelligence store 3504 , that includes a similar set of capabilities and/or functions to the set of modules and functions of the human brain when undertaking an activity, such as for the initial configuration of a robotic process automation (RPA) system 1442 that automates a task performed by an expert human.
  • the platform may include a system that takes input from a functional imaging system to configure, optionally automatically based on matching of attributes between one or more biological systems, such as brain systems, and one or more artificial intelligence systems, a set of artificial intelligence capabilities for a robotic process automation system.
  • Selection and configuration may further comprise selection of inputs to robotic process automation and/or artificial intelligence that are configured at least in part based on functional imaging of the brain while workers undertake tasks, such as selection of visual inputs (such as images from cameras) where vision systems of the brain are highly activated, selection of acoustic inputs where auditory systems of the brain are highly activated, selection of chemical inputs (such as chemical sensors) where olfactory systems of the brain are highly activated, or the like.
  • a biologically aware robotic process automation system may be improved by having initial configuration, or iterative improvement, be guided, either automatically or under developer control, by imaging-derived information collected as workers perform expert tasks that may benefit from automation.
  • FIG. 27 additional details of an embodiment of the platform 604 are provided, in particular relating to elements of the adaptive intelligence layer 614 that facilitate improved edge intelligence, including the adaptive edge compute management system 1400 and the edge intelligence system 1420 .
  • These elements provide a set of systems that adaptively manage “edge” computation, storage and processing, such as by varying storage locations for data and processing locations (e.g., optimized by AI) between on-device storage, local systems, in the network and in the cloud.
  • These elements enable facilitation of a dynamic definition by a user, such as a developer, operator, or host of the platform 102 , of what constitutes the “edge” for purposes of a given application.
  • edge computing capabilities can be defined and deployed to operate on the local area network of an environment, in peer-to-peer networks of devices, or on computing capabilities of local value chain entities 652 .
  • tasks may be intelligently load balanced based on a current context (e.g., network availability, latency, congestion, and the like) and, in an example, one type of data may be prioritized for processing, or one workflow prioritized over another workflow, and the like.
  • a current context e.g., network availability, latency, congestion, and the like
  • edge computing capabilities can be disposed in the network, such as for caching frequently used data at locations that improve input/output performance, reduce latency, or the like.
  • edge computing operations are enabled, under control of a developer or operator, or optionally determined automatically, such as by an expert system or automation system, such as based on detected network conditions for an environment, for a financial entity 652 , or for a network as a whole.
  • edge intelligence 1420 enables adaptation of edge computation (including where computation occurs within various available networking resources, how networking occurs (such as by protocol selection), where data storage occurs, and the like) that is multi-application aware, such as accounting for QoS, latency requirements, congestion, and cost as understood and prioritized based on awareness of the requirements, the prioritization, and the value (including ROI, yield, and cost information, such as costs of failure) of edge computation capabilities across more than one application, including any combinations and subsets of the applications 630 described herein or in the documents incorporated herein by reference.
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 1160 , a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • the platform 604 may include a unified set of adaptive edge computing and other edge intelligence systems 1420 that provide coordinated edge computation and other edge intelligence 1420 capabilities for a set of multiple applications 630 of various types, such as a set of supply chain management applications 21004 , demand management applications 1502 , intelligent product applications 1510 and enterprise resource management applications 1520 that monitor and/or manage a value chain network and a set of value chain network entities 652 .
  • edge intelligence capabilities of the systems and methods described herein may include, but are not limited to, on-premise edge devices and resources, such as local area network resources, and network edge devices, such as those deployed at the edge of a cellular network or within a peripheral data center, both of which may deploy edge intelligence, as described herein, to, for example, carry out intelligent processing tasks at these edge locations before transferring data or other matter, to the primary or core cellular network command or central data center.
  • on-premise edge devices and resources such as local area network resources
  • network edge devices such as those deployed at the edge of a cellular network or within a peripheral data center, both of which may deploy edge intelligence, as described herein, to, for example, carry out intelligent processing tasks at these edge locations before transferring data or other matter, to the primary or core cellular network command or central data center.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a unified set of adaptive edge computing systems that provide coordinated edge computation for a set of applications of at least two types from among a set of demand management applications, a set of supply chain applications, a set of intelligent product applications and a set of enterprise resource management applications for a category of goods.
  • the adaptive edge computing and other edge intelligence systems 1420 may thus provide, in embodiments, intelligence for monitoring, managing, controlling, or otherwise handling a wide range of facilities, devices, systems, environments, and assets, such as supply chain infrastructure facilities 1560 and other value chain network entities 652 that are involved as a product 1510 travels from a point of origin through distribution and retail channels to an environment where it is used by a customer.
  • This unification may provide a number of advantages, including improved monitoring, improved remote control, improved autonomy, improved prediction, improved classification, improved visualization and insight, improved visibility, and others.
  • coordinated intelligence may include, but is not limited to, analytics and processing for monitoring data streams, as described herein, for the purposes of classification, prediction or some other type of analytic modeling.
  • coordinated intelligence methods and systems may be applied in an automated manner in which differing combinations of intelligence assets are applied.
  • the coordinated intelligence system may monitor signals coming from machinery deployed in the environment.
  • the coordinated intelligence system may classify, predict or perform some other intelligent analytics, in combination, for the purpose of, for example, determining a state of a machine, such as a machine in a deteriorated state, in an at-risk state, or some other state.
  • the determination of a state may cause a control system to alter a control regime, for example, slowing or shutting down a machine that is in a deteriorating state.
  • the coordinated intelligence system may coordinate across multiple entities of a value chain, supply chain and the like. For example, the monitoring of the deteriorating machine in the industrial environment may simultaneously occur with analytics related to parts suppliers and availability, product supply and inventory predictions, or some other coordinated intelligence operation.
  • the adaptive edge computing and other edge intelligence systems 1420 may be adapted over time, such as by learning on outcomes 1040 or other operations of the other adaptive intelligent systems 614 , such as to determine which elements collected and/or processed by the adaptive edge computing and other edge intelligence systems 1420 should be made available to which applications 630 , what elements and/or content provide the most benefit, what data should be stored or cached for immediate retrieval, what data can be discarded versus saved, what data is most beneficial to support adaptive intelligent systems 614 , and for other uses.
  • the unified set of adaptive edge computing systems that provide coordinated edge computation include a wide range of systems, such as classification systems 1610 (such as image classification systems, object type recognition systems, and others), video processing systems 1612 (such as video compression systems), signal processing systems 1614 (such as analog-to-digital transformation systems, digital-to-analog transformation systems, RF filtering systems, analog signal processing systems, multiplexing systems, statistical signal processing systems, signal filtering systems, natural language processing systems, sound processing systems, ultrasound processing systems, and many others), data processing systems 1630 (such as data filtering systems, data integration systems, data extraction systems, data loading systems, data transformation systems, point cloud processing systems, data normalization systems, data cleansing system, data deduplication systems, graph-based data storage systems, object-oriented data storage systems, and others), predictive systems 1620 (such as motion prediction systems, output prediction systems, activity prediction systems, fault prediction systems, failure prediction systems, accident prediction systems, event predictions systems, event prediction systems, and many others), configuration systems 1630 (such as protocol selection),
  • the interface is a user interface for a command center dashboard by which an enterprise orchestrates a set of value chain entities related to a type of product.
  • the interface is a user interface of a local management system located in an environment that hosts a set of value chain entities.
  • the local management system user interface facilitates configuration of a set of network connections for the adaptive edge computing systems.
  • the local management system user interface facilitates configuration of a set of data storage resources for the adaptive edge computing systems.
  • the local management system user interface facilitates configuration of a set of data integration capabilities for the adaptive edge computing systems.
  • the local management system user interface facilitates configuration of a set of machine learning input resources for the adaptive edge computing systems.
  • the local management system user interface facilitates configuration of a set of power resources that support the adaptive edge computing systems.
  • the local management system user interface facilitates configuration of a set of workflows that are managed by the adaptive edge computing systems.
  • the interface is a user interface of a mobile computing device that has a network connection to the adaptive edge computing systems.
  • the interface is an application programming interface.
  • the application programming interface facilitates exchange of data between the adaptive edge computing systems and a cloud-based artificial intelligence system.
  • the application programming interface facilitates exchange of data between the adaptive edge computing systems and a real-time operating system of a cloud data management platform.
  • the application programming interface facilitates exchange of data between the adaptive edge computing systems and a computational facility of a cloud data management platform.
  • the application programming interface facilitates exchange of data between the adaptive edge computing systems and a set of environmental sensors that collect data about an environment that hosts a set of value chain network entities.
  • the application programming interface facilitates exchange of data between the adaptive edge computing systems and a set of sensors that collect data about a product.
  • the application programming interface facilitates exchange of data between the adaptive edge computing systems and a set of sensors that collect data published by an intelligent product.
  • the application programming interface facilitates exchange of data between the adaptive edge computing systems and a set of sensors that collect data published by a set of Internet of Things systems that are disposed in an environment that hosts a set of value chain network entities.
  • the set of demand management applications, supply chain applications, intelligent product applications and enterprise resource management applications may include, for example, any of the applications mentioned throughout this disclosure or in the documents incorporated by reference herein.
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 1160 , a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • the VCNP 102 may include a unified set of adaptive intelligent systems 614 that provide coordinated intelligence for a set of various applications, such as demand management applications 1502 , a set of supply chain applications 1500 , a set of intelligent product applications 1510 , a set of enterprise resource management applications 1520 and a set of asset management applications 1530 for a category of goods.
  • a unified set of adaptive intelligent systems 614 that provide coordinated intelligence for a set of various applications, such as demand management applications 1502 , a set of supply chain applications 1500 , a set of intelligent product applications 1510 , a set of enterprise resource management applications 1520 and a set of asset management applications 1530 for a category of goods.
  • the unified set of adaptive intelligence systems include a wide variety of systems described throughout this disclosure and in the documents incorporated herein by reference, such as, without limitation, the edge intelligence systems 1420 , classification systems 1610 , data processing systems 1612 , signal processing systems 1614 , artificial intelligence systems 1160 , prediction systems 1620 , configuration systems 1630 , control systems 1640 , analytic systems 1650 , testing/diagnostic systems 1660 , security systems 1670 and other systems, whether used for edge intelligence or for intelligence within a network, within an application, or in the cloud, as well as to serve various layers of the platform 604 .
  • the edge intelligence systems 1420 classification systems 1610 , data processing systems 1612 , signal processing systems 1614 , artificial intelligence systems 1160 , prediction systems 1620 , configuration systems 1630 , control systems 1640 , analytic systems 1650 , testing/diagnostic systems 1660 , security systems 1670 and other systems, whether used for edge intelligence or for intelligence within a network, within an application, or in the cloud, as well
  • neural networks include neural networks, deep learning systems, model-based systems, expert systems, machine learning systems, rule-based systems, opportunity miners, robotic process automation systems, data transformation systems, data extraction systems, data loading systems, genetic programming systems, image classification systems, video compression systems, analog-to-digital transformation systems, digital-to-analog transformation systems, signal analysis systems, RF filtering systems, motion prediction systems, object type recognition systems, point cloud processing systems, analog signal processing systems, signal multiplexing systems, data fusion systems, sensor fusion systems, data filtering systems, statistical signal processing systems, signal filtering systems, signal processing systems, protocol selection systems, storage configuration systems, power management systems, clustering systems, variation systems, machine learning systems, event prediction systems, autonomous control systems, robotic control systems, robotic process automation systems, data visualization systems, data normalization systems, data cleansing systems, data deduplication systems, graph-based data storage systems, intelligent agent systems, object-oriented data storage systems, self-configuration systems, self-healing systems, self-organizing systems, self-organizing map systems, cost-based routing systems, handshake
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a unified set of adaptive intelligence systems that provide coordinated intelligence for a set of demand management applications, a set of supply chain applications, a set of intelligent product applications and a set of enterprise resource management applications for a category of goods.
  • the unified set of adaptive intelligent systems includes a set of artificial intelligence systems. In embodiments, the unified set of adaptive intelligent systems includes a set of neural networks. In embodiments, the unified set of adaptive intelligent systems includes a set of deep learning systems. In embodiments, the unified set of adaptive intelligent systems includes a set of model-based systems.
  • the unified set of adaptive intelligent systems includes a set of expert systems. In embodiments, the unified set of adaptive intelligent systems includes a set of machine learning systems. In embodiments, the unified set of adaptive intelligent systems includes a set of rule-based systems. In embodiments, the unified set of adaptive intelligent systems includes a set of opportunity miners.
  • the unified set of adaptive intelligent systems includes a set of robotic process automation systems. In embodiments, the unified set of adaptive intelligent systems includes a set of data transformation systems. In embodiments, the unified set of adaptive intelligent systems includes a set of data extraction systems. In embodiments, the unified set of adaptive intelligent systems includes a set of data loading systems. In embodiments, the unified set of adaptive intelligent systems includes a set of genetic programming systems.
  • the unified set of adaptive intelligent systems includes a set of image classification systems. In embodiments, the unified set of adaptive intelligent systems includes a set of video compression systems. In embodiments, the unified set of adaptive intelligent systems includes a set of analog-to-digital transformation systems. In embodiments, the unified set of adaptive intelligent systems includes a set of digital-to-analog transformation systems. In embodiments, the unified set of adaptive intelligent systems includes a set of signal analysis systems.
  • the unified set of adaptive intelligent systems includes a set of RF filtering systems. In embodiments, the unified set of adaptive intelligent systems includes a set of motion prediction systems. In embodiments, the unified set of adaptive intelligent systems includes a set of object type recognition systems. In embodiments, the unified set of adaptive intelligent systems includes a set of point cloud processing systems. In embodiments, the unified set of adaptive intelligent systems includes a set of analog signal processing systems.
  • the unified set of adaptive intelligent systems includes a set of signal multiplexing systems. In embodiments, the unified set of adaptive intelligent systems includes a set of data fusion systems. In embodiments, the unified set of adaptive intelligent systems includes a set of sensor fusion systems. In embodiments, the unified set of adaptive intelligent systems includes a set of data filtering systems. In embodiments, the unified set of adaptive intelligent systems includes a set of statistical signal processing systems.
  • the unified set of adaptive intelligent systems includes a set of clustering systems. In embodiments, the unified set of adaptive intelligent systems includes a set of variation systems. In embodiments, the unified set of adaptive intelligent systems includes a set of machine learning systems. In embodiments, the unified set of adaptive intelligent systems includes a set of event prediction systems. In embodiments, the unified set of adaptive intelligent systems includes a set of autonomous control systems.
  • the unified set of adaptive intelligent systems includes a set of robotic control systems. In embodiments, the unified set of adaptive intelligent systems includes a set of robotic process automation systems. In embodiments, the unified set of adaptive intelligent systems includes a set of data visualization systems. In embodiments, the unified set of adaptive intelligent systems includes a set of data normalization systems. In embodiments, the unified set of adaptive intelligent systems includes a set of data cleansing systems.
  • the unified set of adaptive intelligent systems includes a set of data deduplication systems. In embodiments, the unified set of adaptive intelligent systems includes a set of graph-based data storage systems. In embodiments, the unified set of adaptive intelligent systems includes a set of intelligent agent systems. In embodiments, the unified set of adaptive intelligent systems includes a set of object-oriented data storage systems.
  • the unified set of adaptive intelligent systems includes a set of self-configuration systems. In embodiments, the unified set of adaptive intelligent systems includes a set of self-healing systems. In embodiments, the unified set of adaptive intelligent systems includes a set of self-organizing systems. In embodiments, the unified set of adaptive intelligent systems includes a set of self-organizing map systems.
  • the unified set of adaptive intelligent systems includes a set of cost-based routing systems. In embodiments, the unified set of adaptive intelligent systems includes a set of handshake negotiation systems. In embodiments, the unified set of adaptive intelligent systems includes a set of entity discovery systems. In embodiments, the unified set of adaptive intelligent systems includes a set of cybersecurity systems.
  • the unified set of adaptive intelligent systems includes a set of biometric systems. In embodiments, the unified set of adaptive intelligent systems includes a set of natural language processing systems. In embodiments, the unified set of adaptive intelligent systems includes a set of speech processing systems. In embodiments, the unified set of adaptive intelligent systems includes a set of voice recognition systems.
  • the unified set of adaptive intelligent systems includes a set of sound processing systems. In embodiments, the unified set of adaptive intelligent systems includes a set of ultrasound processing systems. In embodiments, the unified set of adaptive intelligent systems includes a set of artificial intelligence systems. In embodiments, the unified set of adaptive intelligent systems includes a set of rules engine systems.
  • the unified set of adaptive intelligent systems includes a set of workflow automation systems. In embodiments, the unified set of adaptive intelligent systems includes a set of opportunity discovery systems. In embodiments, the unified set of adaptive intelligent systems includes a set of physical modeling systems. In embodiments, the unified set of adaptive intelligent systems includes a set of testing systems.
  • the unified set of adaptive intelligent systems includes a set of diagnostic systems. In embodiments, the unified set of adaptive intelligent systems includes a set of software image propagation systems. In embodiments, the unified set of adaptive intelligent systems includes a set of peer-to-peer network configuration systems. In embodiments, the unified set of adaptive intelligent systems includes a set of RF spectrum management systems.
  • the unified set of adaptive intelligent systems includes a set of network resource management systems. In embodiments, the unified set of adaptive intelligent systems includes a set of storage management systems. In embodiments, the unified set of adaptive intelligent systems includes a set of data management systems. In embodiments, the unified set of adaptive intelligent systems includes a set of intrusion detection systems.
  • the unified set of adaptive intelligent systems includes a set of firewall systems. In embodiments, the unified set of adaptive intelligent systems includes a set of virtualization systems. In embodiments, the unified set of adaptive intelligent systems includes a set of digital twin systems. In embodiments, the unified set of adaptive intelligent systems includes a set of Internet of Things monitoring systems.
  • the unified set of adaptive intelligent systems includes a set of routing systems. In embodiments, the unified set of adaptive intelligent systems includes a set of switching systems. In embodiments, the unified set of adaptive intelligent systems includes a set of indoor location systems. In embodiments, the unified set of adaptive intelligent systems includes a set of geolocation systems.
  • the unified set of adaptive intelligent systems includes a set of parsing systems. In embodiments, the unified set of adaptive intelligent systems includes a set of semantic filtering systems. In embodiments, the unified set of adaptive intelligent systems includes a set of machine vision systems. In embodiments, the unified set of adaptive intelligent systems includes a set of fuzzy logic systems.
  • the unified set of adaptive intelligent systems includes a set of recommendation systems. In embodiments, the unified set of adaptive intelligent systems includes a set of dialog management systems. In embodiments, the set of interfaces includes a demand management interface and a supply chain management interface. In embodiments, the interface is a user interface for a command center dashboard by which an enterprise orchestrates a set of value chain entities related to a type of product.
  • the interface is a user interface of a local management system located in an environment that hosts a set of value chain entities.
  • the local management system user interface facilitates configuration of a set of network connections for the adaptive intelligence systems.
  • the local management system user interface facilitates configuration of a set of data storage resources for the adaptive intelligence systems.
  • the local management system user interface facilitates configuration of a set of data integration capabilities for the adaptive intelligence systems.
  • the local management system user interface facilitates configuration of a set of machine learning input resources for the adaptive intelligence systems. In embodiments, the local management system user interface facilitates configuration of a set of power resources that support the adaptive intelligence systems. In embodiments, the local management system user interface facilitates configuration of a set of workflows that are managed by the adaptive intelligence systems.
  • the interface is a user interface of a mobile computing device that has a network connection to the adaptive intelligence systems.
  • the interface is an application programming interface.
  • the application programming interface facilitates exchange of data between the adaptive intelligence systems and a cloud-based artificial intelligence system.
  • the application programming interface facilitates exchange of data between the adaptive intelligence systems and a real-time operating system of a cloud data management platform.
  • the application programming interface facilitates exchange of data between the adaptive intelligence systems and a computational facility of a cloud data management platform.
  • the application programming interface facilitates exchange of data between the adaptive intelligence systems and a set of environmental sensors that collect data about an environment that hosts a set of value chain network entities. In embodiments, the application programming interface facilitates exchange of data between the adaptive intelligence systems and a set of sensors that collect data about a product.
  • the application programming interface facilitates exchange of data between the adaptive intelligence systems and a set of sensors that collect data published by an intelligent product.
  • the application programming interface facilitates exchange of data between the adaptive intelligence systems and a set of sensors that collect data published by a set of Internet of Things systems that are disposed in an environment that hosts a set of value chain network entities.
  • the set of demand management applications, supply chain applications, intelligent product applications and enterprise resource management applications may include, any of the applications mentioned throughout this disclosure or the documents incorporated herein by reference.
  • the adaptive intelligent systems layer 614 is configured to train and deploy artificial intelligence systems to perform value-chain related tasks.
  • the adaptive intelligent systems layer 614 may be leveraged to manage a container fleet, design a logistics system, control one or more aspects of a logistics system, select packaging attributes of packages in the value chain, design a process to meet regulatory requirements, automate processes to mitigate waste production (e.g., solid waste or waste water), and/or other suitable tasks related to the value-chain.
  • waste production e.g., solid waste or waste water
  • one or more digital twins may be leveraged by the adaptive intelligent systems layer 614 .
  • a digital twin may refer to a digital representation of a physical object (e.g., an asset, a device, a product, a package, a container, a vehicle, a ship, or the like), an environment (e.g., a facility), an individual (e.g., a customer or worker), or other entity (including any of the value chain network entities 652 described herein), or combination thereof.
  • Further examples of physical assets include containers (e.g., boxes, shipping containers, boxes, palates, barrels, and the like), goods/products (e.g., widgets, food, household products, toys, clothing, water, gas, oil, equipment, and the like), components (e.g., chips, boards, screens, chipsets, wires, cables, cards, memory, software components, firmware, parts, connectors, housings, and the like), furniture (e.g., tables, counters, workstations, shelving, etc.), and the like.
  • Examples of devices include computers, sensors, vehicles (e.g., cars, trucks, tankers, trains, forklifts, cranes, and the like), equipment, conveyer belts, and the like.
  • Examples of environments may include facilities (e.g., factories, refineries, warehouses, retail locations, storage buildings, parking lots, airports, commercial buildings, residential buildings, and the like), roads, water ways, cities, countries, land masses, and the like. Examples of different types of physical assets, devices, and environments are referenced throughout the disclosure.
  • a digital twin may be comprised of (e.g., via reference, or by partial or complete integration) other digital twins.
  • a digital twin of a package may include a digital twin of a container and one or more digital twins of one or more respective goods enclosed within the container.
  • one or more digital twins of the packages may be contained in a digital twin of a vehicle traversing a digital twin of a road or may be positioned on a digital twin of a shelf within a digital twin of a warehouse, which would include digital twins of other physical assets and devices.
  • the digital representation for a digital twin may include a set of data structures (e.g., classes of objects) that collectively define a set of properties, attributes, and/or parameters of a represented physical asset, device, or environment, possible behaviors or activities thereof and/or possible states or conditions thereof, among other things.
  • data structures e.g., classes of objects
  • a set of properties of a physical asset may include a type of the physical asset, the shape and/or dimensions of the asset, the mass of the asset, the density of the asset, the material(s) of the asset, the physical properties of the material(s), the chemical properties of the asset, the expected lifetime of the asset, the surface of the physical asset, a price of the physical asset, the status of the physical asset, a location of the physical asset, and/or other properties, as well as identifiers of other digital twins contained within or linked to the digital twin and/or other relevant data sources that may be used to populate the digital twin (such as data sources within the management platform described herein or external data sources, such as environmental data sources that may impact properties represented in the digital twin (e.g., where ambient air pressure or temperature affects the physical dimensions of an asset that inflates or deflates).
  • Examples of a behavior of a physical asset may include a state of matter of the physical asset (e.g., a solid, liquid, plasma or gas), a melting point of the physical asset, a density of the physical asset when in a liquid state, a viscosity of the physical asset when in a liquid state, a freezing point of the physical asset, a density of the physical asset when in a solid state, a hardness of the physical asset when in a solid state, the malleability of the physical asset, the buoyancy of the physical asset, the conductivity of the physical asset, electromagnetic properties of the physical asset, radiation properties, optical properties (e.g., reflectivity, transparency, opacity, albedo, and the like), wave interaction properties (e.g., transparency or opacity to radio waves, reflection properties, shielding properties, or the like), a burning point of the physical asset, the manner by which humidity affects the physical asset, the manner by which water or other liquids affect the physical asset, and the like.
  • the set of properties of a device may include a type of the device, the dimensions of the device, the mass of the device, the density of the density of the device, the material(s) of the device, the physical properties of the material(s), the surface of the device, the output of the device, the status of the device, a location of the device, a trajectory of the device, identifiers of other digital twins that the device is connected to and/or contains, and the like.
  • Examples of the behaviors of a device may include a maximum acceleration of a device, a maximum speed of a device, possible motions of a device, possible configurations of the device, operating modes of the device, a heating profile of a device, a cooling profile of a device, processes that are performed by the device, operations that are performed by the device, and the like.
  • Example properties of an environment may include the dimensions of the environment, environmental air pressure, the temperature of the environment, the humidity of the environment, the airflow of the environment, the physical objects in the environment, currents of the environment (if a body of water), and the like.
  • Examples of behaviors of an environment may include scientific laws that govern the environment, processes that are performed in the environment, rules or regulations that must be adhered to in the environment, and the like.
  • the properties of a digital twin may be adjusted. For example, the temperature of a digital twin, a humidity of a digital twin, the shape of a digital twin, the material of a digital twin, the dimensions of a digital twin, or any other suitable parameters may be adjusted to conform to current status data and/or to a predicted status of a corresponding entity.
  • a digital twin may be rendered by a computing device, such that a human user can view a digital representation of a set of physical assets, devices, or other entities, and/or an environment thereof.
  • the digital twin may be rendered and provided as an output, or may provide an output, to a display device.
  • the digital twin may be rendered and output in an augmented reality and/or virtual reality display.
  • a user may view a 3D rendering of an environment (e.g., using monitor or a virtual reality headset). While doing so, the user may inspect digital twins of physical assets or devices in the environment.
  • a user may view processes being performed with respect to one or more digital twins (e.g., inventorying, loading, packing, shipping, and the like).
  • a user may provide input that controls one or more properties of a digital twin via a graphical user interface.
  • the adaptive intelligent systems layer 614 is configured to execute simulations using the digital twin. For example, the adaptive intelligent systems layer 614 may iteratively adjust one or more parameters of a digital twin and/or one or more embedded digital twins. In embodiments, the adaptive intelligent systems layer 614 may, for each set of parameters, execute a simulation based on the set of parameters and may collect the simulation outcome data resulting from the simulation. Put another way, the adaptive intelligent systems layer 614 may collect the properties of the digital twin and the digital twins within or containing the digital twin used during the simulation as well as any outcomes stemming from the simulation.
  • the adaptive intelligent systems layer 614 can vary the materials of the shipping container and can execute simulations that outcomes resulting from different combinations.
  • an outcome can be whether the goods contained in the shipping container arrive to a destination undamaged.
  • the adaptive intelligent systems layer 614 may vary the external temperatures of the container (e.g., a temperature property of the digital twin of an environment of the container may be adjusted between simulations or during a simulation), the dimensions of the container, the products inside (represented by digital twins of the products) the container, the motion of the container, the humidity inside the container, and/or any other properties of the container, the environment, and/or the contents in the container.
  • the simulations may adhere to scientific formulas, such as ones reflecting principles or laws of physics, chemistry, materials science, biology, geometry, or the like.
  • a simulation of the physical behavior of an object may adhere to the laws of thermodynamics, laws of motion, laws of fluid dynamics, laws of buoyancy, laws of heat transfer, laws of cooling, and the like.
  • the simulation may conform to the physical limitations and scientific laws, such that the outcomes of the simulations mimic real world outcomes.
  • the outcome from a simulation can be presented to a human user, compared against real world data (e.g., measured properties of a container, the environment of the container, the contents of the container, and resultant outcomes) to ensure convergence of the digital twin with the real world, and/or used to train machine learning models.
  • real world data e.g., measured properties of a container, the environment of the container, the contents of the container, and resultant outcomes
  • FIG. 38 illustrates example embodiments of a system for controlling and/or making decisions, predictions, and/or classification on behalf of a value chain system 2030 .
  • an artificial intelligence system 2010 leverages one or more machine-learned models 2004 to perform value chain-related tasks on behalf of the value chain system 2030 and/or to make decisions, classifications, and/or predictions on behalf of the value chain system 2030 .
  • a machine learning system 2002 trains the machine learned models 2004 based on training data 2062 , outcome data 2060 , and/or simulation data 2022 .
  • the term machine-learned model may refer to any suitable type of model that is learned in a supervised, unsupervised, or hybrid manner
  • machine-learned models include neural networks (e.g., deep neural networks, convolution neural networks, and many others), regression based models, decision trees, hidden forests, Hidden Markov models, Bayesian models, and the like.
  • the artificial intelligence system 2010 and/or the value chain system 2030 may provide outcome data 2060 to the machine-learning system 2002 that relates to a determination (e.g., decision, classification, prediction) made by the artificial intelligence system 2010 based in part on the one or more machine-learned models and the input to those models.
  • the machine learning system may in-turn reinforce/retrain the machine-learned models 2004 based on the feedback.
  • the machine-learning system 2002 may train the machine-learning models based on simulation data 2022 generated by the digital twin simulation system 2020 .
  • the digital twin simulation system 2020 may be instructed to run specific simulations using one or more digital twins that represent objects and/or environments that are managed, maintained, and/or monitored by the value chain system. In this way, the digital twin simulation system 2020 may provide richer data sets that the machine-learning system 2002 may use to train/reinforce the machine-learned models. Additionally or alternatively, the digital twin simulation system 2020 may be leveraged by the artificial intelligence system 2010 to test a decision made by the artificial intelligence system 2010 before providing the decision to the value chain entity.
  • a machine learning system 2002 may receive training data 2062 , outcome data 2060 , and/or simulation data 2022 .
  • the training data may be data that is used to initially train a model.
  • the training data may be provided by a domain expert, collected from various data sources, and/or obtained from historical records and/or scientific experimentation.
  • the training data 2062 may include quantified properties of an item or environment and outcomes relating from the quantified properties.
  • the training data may be structured in n-tuples, whereby each tuple includes an outcome and a respective set of properties relating to the outcome.
  • the outcome data 2060 includes real world data (e.g., data measured or captured from one or more of IoT sensors, value chain entities, and/or other sources).
  • the outcome data may include an outcome and properties relating to the outcome.
  • Outcome data may be provided by the value chain system 2030 leveraging the artificial intelligence system 2010 and/or other data sources during operation of the value chain entity system 2010 .
  • the value chain entity system 2010 , the artificial intelligence system 2010 , as well as any other data source 2050 may output data relating to the outcome to the machine learning system 2002 .
  • this data may be provided to the machine-learning system via an API of the adaptive intelligent systems layer 614 .
  • the adaptive intelligent systems layer 614 may obtain data from other types of external data sources that are not necessarily a value chain entity but may provide insightful data. For example, weather data, stock market data, news events, and the like may be collected, crawled, subscribed to, or the like to supplement the outcome data (and/or training data and/or simulation data).
  • the machine learning system 2002 may receive simulation data 2022 from the digital twin simulation system 2020 .
  • Simulation data 2022 may be any data relating to a simulation using a digital twin. Simulation data 2022 may be similar to outcome data 2060 , but the results are simulated results from an executed simulation rather than real-world data.
  • simulation data 2022 may include the properties of the digital twin and any other digital twins that were used to perform the simulation and the outcomes stemming therefrom.
  • the digital twin simulation system 2020 may iteratively adjust the properties of a digital twin, as well as other digital twins that are contained or contain the digital twin.
  • the digital twin simulation system 2020 may provide the properties of the simulation (e.g., the properties of all the digital twins involved in the simulation) to the artificial intelligence system 2010 , which then outputs predictions, classifications, or any other decisions to the digital twin simulation system 2020 .
  • the digital twin simulation system 2020 may use the decisions from the artificial intelligence system 2010 to execute the simulation (which may result in a series of decisions stemming from a state change in the simulation).
  • the digital twin simulation system 2020 may output the properties used to run the simulation to the machine learning system 2002 , any decisions from the artificial intelligence system 2010 used by the digital twin simulation system 2020 , and outcomes from the simulation to the machine learning system 2002 , such that the properties, decisions, and outcomes of the simulation are used to further train the model(s) used by the artificial intelligence system during the simulation.
  • training data, outcome data 2060 , and/or simulation data 2022 may be fed into a data lake (e.g., a Hadoop data lake).
  • the machine learning system 2002 may structure the data from the data lake.
  • the machine learning system 2002 may train/reinforce the models using the collected data to improve the accuracy of the models (e.g., minimize the error value of the model).
  • the machine learning system may execute machine-learning algorithms on the collected data (e.g., training data, outcome data, and/or simulation data) to obtain the model. Depending on the type of model, the machine-learning algorithm will vary.
  • Examples of learning algorithms/models include (e.g., deep neural networks, convolution neural networks, and many others as described throughout this disclosure), statistical models (e.g., regression-based models and many others), decision trees and other decision models, random/hidden forests, Hidden Markov models, Bayesian models, and the like.
  • the machine-learning system 2002 may train the model on scenarios not yet encountered by the value chain system 2030 . In this way, the resultant models will have less “unexplored” feature spaces, which may lead to improved decisions by the artificial intelligence system 2010 .
  • the properties of a digital twin may be updated/corrected when a real-world behavior differs from that of the digital twin. Examples are provided below.
  • FIG. 39 illustrates an example of a container fleet management system 2070 that interfaces with the adaptive intelligent systems layer 614 .
  • a container fleet management system 2070 may be configured to automate one or more aspects of the value chain as it applies to containers and shipping.
  • the container fleet management system 2070 may be include one or more software modules that are executed by one or more server devices.
  • These software modules may be configured to select containers to use (e.g., a size of container, the type of the container, the provider of the container, etc.) for a set of one or more shipments, schedule delivery/pickup of container, selection of shipping routes, determining the type of storage for a container (e.g., outdoor or indoor), select a location of each container while awaiting shipping, manage bills of lading and/or other suitable container fleet management tasks.
  • the machine-learning system 2002 trains one or more models that are leveraged by the artificial intelligence system 2010 to make classifications, predictions, and/or other decisions relating to container fleet management.
  • a model 2004 is trained to select types of containers given one or more task-related features to maximize the likelihood of a desired outcome (e.g., that the contents of the container arrive in a timely manner with minimal loss at the lowest possible cost).
  • the machine-learning system 2002 may train the models using n-tuples that include the task-related features pertaining to a particular event and one or more outcomes associated with the particular event.
  • task-related features for a particular event may include, but are not limited to, the type of container used, the contents of the container, properties of the container contents (e.g., cost, perishability, temperature restrictions, and the like), the source and destination of the container, whether the container is being shipped via truck, rail, or ship, the time of year, the cost of each container, and/or other relevant features.
  • outcomes relating to the particular event may include whether the contents arrived safely, replacement costs (if any) associated with any damage or loss, total shipping time, and/or total cost of shipment (e.g., how much it cost to ship container).
  • simulations that simulate different shipping events may be run to richen the data used to train the model. For instance, simulations may be run for different combinations of ports and/or train depots for different combinations of sources, destinations, products, and times of year.
  • different digital twins may be generated to represent the different combinations (e.g., digital twins of products, containers, and shipping-related environments), whereby one or more properties of the digital twins are varied for different simulations and the outcomes of each simulation may be recorded in a tuple with the proprieties.
  • the model may be trained on certain combinations of routes, contents, time of year, container type, and/or cost that may not have been previously encountered in the real-world outcome data.
  • Other examples of training a container fleet management model may include a model that is trained to determine where a container should be stored in a storage facility (e.g., where in a stack, indoors or outdoors, and/or the like) given the contents of the container, when the container needs to be moved, the type of container, the location, the time of year, and the like.
  • the artificial intelligence system 2010 may use the above-discussed models 2004 to make container fleet management decisions on behalf of a container fleet management system 2070 given one or more features relating to a task or event.
  • the artificial intelligence system 2010 may select a type of container (e.g., materials of the container, the dimensions of the container, the brand of the container, and the like) to use for a particular shipment.
  • the container fleet management system 2070 may provide the features of an upcoming shipment to the artificial intelligence system 2010 . These features may include what is being shipped (e.g., the type(s) of goods in the shipment), the size of the shipment, the source and destination, the date when the shipment is to be sent off, and/or the desired date or range of dates for delivery.
  • the artificial intelligence system 2010 may feed these features into one or more of the models discussed above to obtain one or more decisions. These decisions may include which type of container to use and/or which shipping routes to use, whereby the decisions may be selected to minimize overall shipping costs (e.g., costs for container and transit+any replacement costs).
  • the container fleet management system 2070 may then initiate the shipping event using the decision(s) made by the artificial intelligence system 2010 . Furthermore, after the shipping event, the outcomes of the event (e.g., total shipping time, any reported damages or loss, replacement costs, total costs) may be reported to the machine-learning system 2002 to reinforce the models used to make the decisions.
  • the output of the container fleet management system 2070 and/or the other value chain entity data sources 2050 may be used to update one or more properties of one or more digital twins via the digital twin system 2020 .
  • FIG. 40 illustrates an example of a logistics design system that interfaces with the adaptive intelligent systems layer 614 .
  • a logistics design system may be configured to design one or more aspects of a logistics solution.
  • the logistics design system may be configured to receive one or more logistics factors (e.g., from a user via a GUI).
  • logistics factors may include one or more present conditions, historical conditions, or future conditions of an organization (or potential organization) that are relevant to forming a logistics solution.
  • logistics factors may include, but are not limited to the type(s) of products being produced/farmed/shipped, features of those products (e.g., dimensions, weights, shipping requirements, shelf life, etc.), locations of manufacturing sites, locations of distribution facilities, locations of warehouses, locations of customer bases, market penetration in certain areas, expansion locations, supply chain features (e.g., required parts/supplies/resources, suppliers, supplier locations, buyers, buyer locations), and/or the like) and may determine one or more design recommendations based on the factors.
  • features of those products e.g., dimensions, weights, shipping requirements, shelf life, etc.
  • locations of manufacturing sites e.g., dimensions, weights, shipping requirements, shelf life, etc.
  • locations of distribution facilities e.g., locations of distribution facilities, locations of warehouses, locations of customer bases, market penetration in certain areas, expansion locations, supply chain features (e.g., required parts/supplies/resources, suppliers, supplier locations, buyers, buyer locations), and/or the like) and may determine one or
  • Examples of design recommendations may include supply chain recommendations (e.g., proposed suppliers (e.g., resource or parts suppliers), implementations of a smart inventory systems that order on-demand parts from available suppliers, and the like), storage and transport recommendations (e.g., proposed shipping routes, proposed shipping types (e.g., air, freight, truck, ship), proposed storage development (e.g., locations and/or dimensions of new warehouses), infrastructure recommendations (e.g., updates to machinery, adding cooled storage, adding heated storage, or the like), and combinations thereof.
  • the logistics design system determines the recommendations to optimize an outcome. Examples of outcomes can include manufacturing times, manufacturing costs, shipping times, shipping costs, loss rate, environmental impact, compliance to a set of rules/regulations, and the like. Examples of optimizations include increased production throughput, reduced production costs, reduced shipping costs, decreased shipping times, reduced carbon footprint, and combinations thereof.
  • the logistics design system may interface with the artificial intelligence system 2010 to provide the logistics factors and to receive design recommendations that are based thereon.
  • the artificial intelligence system 2010 may leverage one or more machine-learned models 2004 (e.g., logistics design recommendations models) to determine a recommendation.
  • a logistics design recommendation model may be trained to optimize one or more outcomes given a set of logistics factors.
  • a logistics design recommendation model trained to design supply chains may identify a set of suppliers that can supply a given manufacturer, the location of the manufacturer, the supplies needed, and/or other factors. The set of suppliers may then be used to implement an on-demand supply side inventory.
  • the logistics design recommendation may take the same features of another manufacturer and recommend the purchase and use of one or more 3D printers.
  • the artificial intelligence system 2010 may leverage the digital twin system 2020 to generate a digital twin of a logistics system that implements the logistics design recommendation (and, in some embodiments, alternative systems that implement other design recommendations).
  • the digital twin system 1700 may receive the design recommendations and may generate a digital twin of a logistics environment that mirrors the recommendations.
  • the artificial intelligence system 2010 may leverage the digital twin of the logistics environment to run simulations on the proposed solution.
  • the digital twin system 1700 may display the digital twin of the logistics environment to a user via a display device (e.g., a monitor or a VR headset). In embodiments, the user may view the simulations in the digital twin.
  • the digital twin system 1700 may provide a graphical user interface that the user may interact with to adjust the design of the logistics environment to adjust the design.
  • the design provided (at least in part) by a user may also be represented in a digital twin of a logistics environment, whereby the digital twin system 2020 may perform simulations using the digital twin.
  • the simulations run by the digital twin system 1700 may be used to train the recommendation models.
  • the logistics system of the organization may be configured to report (e.g., via sensors, computing devices, manual human input) outcome data corresponding to the design recommendations to the machine learning system 2002 , which may use the outcome data to reinforce the logistics design recommendation models.
  • FIG. 41 illustrates an example of a packaging design system that interfaces with the adaptive intelligent systems layer 614 .
  • the packaging design system may be configured to design one or more aspects of packaging for a physical object being conveyed in the value chain network.
  • the packaging design system may select one or more packaging attributes (e.g., size, material, padding, etc.) of the packaging to optimize one or more outcomes associated with the transport of the physical object.
  • the packaging attributes may be selected to reduce costs, decrease loss/damage, decrease weight, decrease plastic or other non-biodegradable waste, or the like.
  • the packaging design system leverages the artificial intelligence system 2010 to obtain packaging attribute recommendations.
  • the packaging design system may provide one or more features of the physical object.
  • the features of the physical object may include the dimensions of the physical object, the mass of the physical object, the source of the physical object, one or more potential destinations of the physical object, the manner by which the physical object is shipped, and the like.
  • the packaging design system may further provide one or more optimization goals for the package design (e.g., reduce cost, reduce damage, reduce environmental impact).
  • the artificial intelligence system 2010 may determine one or more recommended packaging attributes based on the physical asset features and the given objective.
  • the packaging design system receives the packaging attributes and generates a package design based thereon.
  • the package design may include a material to be used, the external dimensions of the packaging, the internal dimensions of the packaging, the shape of the packaging, the padding/stuffing for the packaging, and the like.
  • the packaging design system may provide a packaging design to the digital twin system 2020 , which generates a digital twin of the packaging and physical asset based on the packaging design.
  • the digital twin of the packaging and physical asset may be used to run simulations that test the packaging (e.g., whether the packaging holds up in shipping, whether the packaging provides adequate insulation/padding, and the like).
  • the results of the simulation may be returned to the packaging design system, which may output the results to a user.
  • the user may accept the packaging design, may adjust the packaging design, or may reject the design.
  • the digital twin system may run simulations on one or more digital twins to test different conditions that the package may be subjected to (e.g., outside in the snow, rocking in a boat, being moved by a forklift, or the like).
  • the digital twin system may output the results of a simulation to the machine-learning system 2002 , which can train/reinforce the packaging design models based on the properties used to run the simulation and the outcomes stemming therefrom.
  • the machine-learning system 2002 may receive outcome data from the packaging design system and/or other value chain entity data sources (e.g., smart warehouses, user feedback, and the like). The machine-learning system 2002 may use this outcome data to train/reinforce the packaging design models. Furthermore, in some embodiments, the outcome data may be used by the digital twin system 2020 to update/correct any incorrect assumptions used by the digital twin system (e.g., the flexibility of a packaging material, the water resistance of a packaging material, and the like).
  • outcome data may be used by the digital twin system 2020 to update/correct any incorrect assumptions used by the digital twin system (e.g., the flexibility of a packaging material, the water resistance of a packaging material, and the like).
  • FIG. 42 illustrates examples of a waste mitigation system that interfaces with the adaptive intelligent systems layer 614 .
  • the waste mitigation system is configured to analyze a process within the value chain (e.g., manufacturing of a product, oil refining, fertilization, water treatment, or the like) to mitigate waste (e.g., solid waste, wastewater, discarded packaging, wasted energy, wasted time, wasted resources, or other waste).
  • the waste mitigation system may interface with the artificial intelligence system 2010 to automate one or more processes to mitigate waste.
  • the artificial intelligence system 2010 may provide control decisions to the waste mitigation system to mitigate solid waste production.
  • waste production may include excess plastic or other non-biodegradable waste, hazardous or toxic waste (e.g., nuclear waste, petroleum coke, or the like), and the like.
  • the artificial intelligence system 2010 may receive one or more features of the process (or “process features”). Examples of process features may include, but are not limited to, the steps in the process, the materials being used, the properties of the materials being used, and the like.
  • the artificial intelligence system 2010 may leverage one or more machine-learned models to control the process. In embodiments, the machine-learned models may be trained to classify a waste condition and/or the cause of the waste condition.
  • the artificial intelligence system 2010 may determine or select a waste mitigation solution based on the classified waste condition. For example, in some embodiments, the artificial intelligence system 2010 may apply rules-based logic to determine an adjustment to make to the process to reduce or resolve the waste condition. Additionally, or alternatively, the artificial intelligence may leverage a model that recommends an adjustment to make to the process to reduce or resolve the waste condition.
  • the artificial intelligence system 2010 may leverage the digital twin system 2020 to mitigate the waste produced by a process.
  • the digital twin system 2020 may execute iterative simulations of the process in a digital twin of the environment in which the process is performed.
  • the artificial intelligence system 2010 may monitor the results of the simulation to determine a waste condition and/or the cause of the waste condition.
  • the artificial intelligence system 2010 may adjust one or more aspects of the process to determine whether the adjustments mitigated the waste condition, worsened the waste condition, or had no effect.
  • the artificial intelligence system 2010 may adjust other aspects of the process to determine if an improvement can be realized.
  • the artificial intelligence system 2010 may perform a genetic algorithm when iteratively adjusting the aspects of the process in the digital twin simulations. In these embodiments, the artificial intelligence system 2010 may identify aspects of the process that can be adjusted to mitigate the waste production.
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 614 (including artificial intelligence 1160 ), a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 614 (including artificial intelligence 1160 ), a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • the adaptive intelligence systems layer 614 may further include a set of automated project management facilities 21006 that provide automated recommendations for a set of value chain project management tasks based on processing current status information, a set of application outputs and/or a set of outcomes 1040 for a set of demand management applications 1502 , a set of supply chain applications 1500 , a set of intelligent product applications 1510 , a set of asset management applications 1530 and a set of enterprise resource management applications 1520 for a category of goods.
  • a set of automated project management facilities 21006 that provide automated recommendations for a set of value chain project management tasks based on processing current status information, a set of application outputs and/or a set of outcomes 1040 for a set of demand management applications 1502 , a set of supply chain applications 1500 , a set of intelligent product applications 1510 , a set of asset management applications 1530 and a set of enterprise resource management applications 1520 for a category of goods.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a set of project management facilities that provide automated recommendations for a set of value chain project management tasks based on processing current status information and a set of outcomes for a set of demand management applications, a set of supply chain applications, a set of intelligent product applications and a set of enterprise resource management applications for a category of goods.
  • the set of project management facilities are configured to manage a wide variety of types of projects, such as procurement projects, logistics projects, reverse logistics projects, fulfillment projects, distribution projects, warehousing projects, inventory management projects, product design projects, product management projects, shipping projects, maritime projects, loading or unloading projects, packing projects, purchasing projects, marketing projects, sales projects, analytics projects, demand management projects, demand planning projects, resource planning projects and many others.
  • projects such as procurement projects, logistics projects, reverse logistics projects, fulfillment projects, distribution projects, warehousing projects, inventory management projects, product design projects, product management projects, shipping projects, maritime projects, loading or unloading projects, packing projects, purchasing projects, marketing projects, sales projects, analytics projects, demand management projects, demand planning projects, resource planning projects and many others.
  • the project management facilities are configured to manage a set of procurement projects. In embodiments, the project management facilities are configured to manage a set of logistics projects. In embodiments, the project management facilities are configured to manage a set of reverse logistics projects. In embodiments, the project management facilities are configured to manage a set of fulfillment projects.
  • the project management facilities are configured to manage a set of distribution projects. In embodiments, the project management facilities are configured to manage a set of warehousing projects. In embodiments, the project management facilities are configured to manage a set of inventory management projects. In embodiments, the project management facilities are configured to manage a set of product design projects.
  • the project management facilities are configured to manage a set of product management projects. In embodiments, the project management facilities are configured to manage a set of shipping projects. In embodiments, the project management facilities are configured to manage a set of maritime projects. In embodiments, the project management facilities are configured to manage a set of loading or unloading projects.
  • the project management facilities are configured to manage a set of packing projects. In embodiments, the project management facilities are configured to manage a set of purchasing projects. In embodiments, the project management facilities are configured to manage a set of marketing projects. In embodiments, the project management facilities are configured to manage a set of sales projects.
  • the project management facilities are configured to manage a set of analytics projects. In embodiments, the project management facilities are configured to manage a set of demand management projects. In embodiments, the project management facilities are configured to manage a set of demand planning projects. In embodiments, the project management facilities are configured to manage a set of resource planning projects.
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 614 (including artificial intelligence 1160 ), a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 614 (including artificial intelligence 1160 ), a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a set of project management facilities that provide automated recommendations for a set of value chain project management tasks based on processing current status information and a set of outcomes for a set of demand management applications, a set of supply chain applications, a set of intelligent product applications and a set of enterprise resource management applications for a category of goods.
  • the adaptive intelligent systems layer 614 may further include a set of process automation facilities 1710 that provide automated recommendations for a set of value chain process tasks 1710 that provide automated recommendations for a set of value chain processes based on processing current status information, a set of application outputs and/or a set of outcomes 1040 for a set of demand management applications 1502 , a set of supply chain applications 1500 , a set of intelligent product applications 1510 , a set of asset management applications 1530 and a set of enterprise resource management applications 1520 for a category of goods.
  • the process automation facilities 1710 may be used with basic rule-based training and recommendations. This may relate to following a set of rules that an expert has articulated such as when a trigger occurs, undertake a task.
  • the process automation facilities 1710 may utilize deep learning to observe interactions such as deep learning on outcomes to learn to recommend decisions or tasks that produce a highest return on investment (ROI) or other outcome-based yield.
  • the process automation facilities 1710 may be used to provide collaborative filtering such as look at a set of experts that are most similar in terms of work done and tasks completed being most similar.
  • the underlying software may be used to find customers similar to another set of customers to sell to, make a different offering to, or change price accordingly.
  • purchasing patterns may be determined for that customer segment such as knowledge of cost and pricing patterns for that customer.
  • This information may be used to learn to focus a next set of activities around pricing, promotion, demand management towards an ideal that may be based on deep learning or rules or collaborative filtering type work trying to leverage off of similar decisions made by similarly situated people (e.g., recommending movies to a similar cohort of people).
  • the set of facilities that provide automated recommendations for a set of value chain process tasks provide recommendations involving a wide range of types of activities, such as, without limitation, product configuration activities, product selection activities for a customer, supplier selection activities, shipper selection activities, route selection activities, factory selection activities, product assortment activities, product management activities, logistics activities, reverse logistics activities, artificial intelligence configuration activities, maintenance activities, product support activities, product recommendation activities and many others.
  • the automated recommendations relate to a set of product configuration activities. In embodiments, the automated recommendations relate to a set of product selection activities for a customer. In embodiments, the automated recommendations relate to a set of supplier selection activities. In embodiments, the automated recommendations relate to a set of shipper selection activities.
  • the automated recommendations relate to a set of route selection activities. In embodiments, the automated recommendations relate to a set of factory selection activities. In embodiments, the automated recommendations relate to a set of product assortment activities. In embodiments, the automated recommendations relate to a set of product management activities. In embodiments, the automated recommendations relate to a set of logistics activities.
  • the automated recommendations relate to a set of reverse logistics activities. In embodiments, the automated recommendations relate to a set of artificial intelligence configuration activities. In embodiments, the automated recommendations relate to a set of maintenance activities. In embodiments, the automated recommendations relate to a set of product support activities. In embodiments, the automated recommendations relate to a set of product recommendation activities.
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 614 (including artificial intelligence 1160 ), a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 614 (including artificial intelligence 1160 ), a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • an information technology system may include: a cloud-based management platform for a value chain network with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; and a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; wherein a set of routing facilities generate a set of routing instructions for routing information among a set of nodes in the value chain network based on current status information for the value chain network.
  • the adaptive intelligent systems layer 614 may further include a set of routing facilities 1720 that generate a set of routing instructions for routing information among a set of nodes in the value chain network, such as based on processing current status information 1730 , a set of application outputs and/or a set of outcomes 1040 , or other information collected by or used in the VCNP 102 .
  • Routing may include routing for the benefit of a set of demand management applications 1502 , a set of supply chain applications 1500 , a set of intelligent product applications 1510 , a set of asset management applications 1530 and a set of enterprise resource management applications 1520 for a category of goods.
  • the set of routing facilities that generate a set of routing instructions for routing information among a set of nodes in the value chain network use a wide variety of routing systems or configurations, such as involving, without limitation, priority-based routing, master controller routing, least cost routing, rule-based routing, genetically programmed routing, random linear network coding routing, traffic-based routing, spectrum-based routing, RF condition-based routing, energy-based routing, latency-sensitive routing, protocol compatibility based routing, dynamic spectrum access routing, peer-to-peer negotiated routing, queue-based routing, and others.
  • the routing includes priority-based routing. In embodiments, the routing includes master controller routing. In embodiments, the routing includes least cost routing. In embodiments, the routing includes rule-based routing. In embodiments, the routing includes genetically programmed routing.
  • the routing includes random linear network coding routing. In embodiments, the routing includes traffic-based routing. In embodiments, the routing includes spectrum-based routing.
  • the routing includes RF condition-based routing. In embodiments, the routing includes energy-based routing. In embodiments, the routing includes latency-sensitive routing.
  • the routing includes protocol compatibility-based routing.
  • the routing includes dynamic spectrum access routing. In embodiments, the routing includes peer-to-peer negotiated routing. In embodiments, the routing includes queue-based routing.
  • the status information for the value chain network involves a wide range of states, events, workflows, activities, occurrences, or the like, such as, without limitation, traffic status, congestion status, bandwidth status, operating status, workflow progress status, incident status, damage status, safety status, power availability status, worker status, data availability status, predicted system status, shipment location status, shipment timing status, delivery status, anticipated delivery status, environmental condition status, system diagnostic status, system fault status, cybersecurity status, compliance status, demand status, supply status, price status, volatility status, need status, interest status, aggregate status for a group or population, individual status, and many others.
  • states, events, workflows, activities, occurrences, or the like such as, without limitation, traffic status, congestion status, bandwidth status, operating status, workflow progress status, incident status, damage status, safety status, power availability status, worker status, data availability status, predicted system status, shipment location status, shipment timing status, delivery status, anticipated delivery status, environmental condition status, system diagnostic status, system fault status, cybersecurity status, compliance status, demand status, supply status, price status, volatility status, need
  • the status information involves traffic status. In embodiments, the status information involves congestion status. In embodiments, the status information involves bandwidth status. In embodiments, the status information involves operating status. In embodiments, the status information involves workflow progress status.
  • the status information involves incident status. In embodiments, the status information involves damage status. In embodiments, the status information involves safety status.
  • the status information involves power availability status. In embodiments, the status information involves worker status. In embodiments, the status information involves data availability status.
  • the status information involves predicted system status. In embodiments, the status information involves shipment location status. In embodiments, the status information involves shipment timing status. In embodiments, the status information involves delivery status.
  • the status information involves anticipated delivery status. In embodiments, the status information involves environmental condition status.
  • the status information involves system diagnostic status. In embodiments, the status information involves system fault status. In embodiments, the status information involves cybersecurity status. In embodiments, the status information involves compliance status.
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 614 (including artificial intelligence 1160 ), a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 614 (including artificial intelligence 1160 ), a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a dashboard for managing a set of digital twins, wherein at least one digital twin represents a set of supply chain entities, workflows and assets and at least one other digital twin represents a set of demand management entities and workflows.
  • the VCNP 604 may further include a dashboard 4200 for managing a set of digital twins 1700 .
  • this may include different twins, such as where one digital twin 1700 represents a set of supply chain entities, workflows and assets and another digital twin 1700 represents a set of demand management entities and workflows.
  • managing a set of digital twins 1700 may refer to configuration (e.g., via the dashboard 4200 ) as described in the disclosure.
  • the digital twin 1700 may be configured through use of a digital twin configuration system to set up and manage the enterprise digital twins and associated metadata of an enterprise, to configure the data structures and data listening threads that power the enterprise digital twins, and to configure features of the enterprise digital twins, including access features, processing features, automation features, reporting features, and the like, each of which may be affected by the type of enterprise digital twin (e.g., based on the role(s) that it serves, the entities it depicts, the workflows that it supports or enables and the like).
  • the digital twin configuration system may receive the types of digital twins that may be supported for the enterprise, as well as the different objects, entities, and/or states that are to be depicted in each type of digital twin.
  • the digital twin configuration system may determine one or more data sources and types of data that feed or otherwise support each object, entity, or state that is depicted in the respective type of digital twin and may determine any internal or external software requests (e.g., API calls) that obtain the identified data types or other suitable data acquisitions mechanisms, such as webhooks, that may configured to automatically receive data from an internal or external data source
  • the digital twin configuration system may determine internal and/or external software requests that support the identified data types by analyzing the relationships between the different types of data that correspond to a particular state/entity/object and the granularity thereof.
  • a user may define (e.g., via a GUI) the data sources and/or software requests and/or other data acquisition mechanisms that support the respective data types that are depicted in a respective digital twin.
  • the user may indicate the data source that may be accessed and the types of data to be obtained from the respective data source.
  • the dashboard may be used to configure the digital twins 1700 for use in collection, processing, and/or representation of information collected in the platform 604 , such as status information 1730 , such as for the benefit of a set of demand management applications 1502 , a set of supply chain applications 1500 , a set of intelligent product applications 1510 , a set of asset management applications 1530 and a set of enterprise resource management applications 1520 for a category of goods.
  • status information 1730 such as for the benefit of a set of demand management applications 1502 , a set of supply chain applications 1500 , a set of intelligent product applications 1510 , a set of asset management applications 1530 and a set of enterprise resource management applications 1520 for a category of goods.
  • the dashboard for managing a set of digital twins wherein at least one digital twin represents a set of supply chain entities and workflows and at least one other digital twin represents a set of demand management entities and workflows.
  • the entities and workflows relate to a set of products of an enterprise. In embodiments, the entities and workflows relate to a set of suppliers of an enterprise. In embodiments, the entities and workflows relate to a set of producers of a set of products. In embodiments, the entities and workflows relate to a set of manufacturers of a set of products.
  • the entities and workflows relate to a set of retailers of a line of products. In embodiments, the entities and workflows relate to a set of businesses involved in an ecosystem for a category of products. In embodiments, the entities and workflows relate to a set of owners of a set of assets involved in a value chain for a set of products. In embodiments, the entities and workflows relate to a set of operators of a set of assets involved in a value chain for a set of products.
  • the entities and workflows relate to a set of operating facilities. In embodiments, the entities and workflows relate to a set of customers. In embodiments, the entities and workflows relate to a set of consumers. In embodiments, the entities and workflows relate to a set of workers.
  • the entities and workflows relate to a set of mobile devices. In embodiments, the entities and workflows relate to a set of wearable devices. In embodiments, the entities and workflows relate to a set of distributors. In embodiments, the entities and workflows relate to a set of resellers.
  • the entities and workflows relate to a set of supply chain infrastructure facilities. In embodiments, the entities and workflows relate to a set of supply chain processes. In embodiments, the entities and workflows relate to a set of logistics processes. In embodiments, the entities and workflows relate to a set of reverse logistics processes.
  • the entities and workflows relate to a set of demand prediction processes. In embodiments, the entities and workflows relate to a set of demand management processes. In embodiments, the entities and workflows relate to a set of demand aggregation processes. In embodiments, the entities and workflows relate to a set of machines.
  • the entities and workflows relate to a set of ships. In embodiments, the entities and workflows relate to a set of barges. In embodiments, the entities and workflows relate to a set of warehouses. In embodiments, the entities and workflows relate to a set of maritime ports.
  • the entities and workflows relate to a set of airports. In embodiments, the entities and workflows relate to a set of airways. In embodiments, the entities and workflows relate to a set of waterways. In embodiments, the entities and workflows relate to a set of roadways.
  • the entities and workflows relate to a set of railways. In embodiments, the entities and workflows relate to a set of bridges. In embodiments, the entities and workflows relate to a set of tunnels. In embodiments, the entities and workflows relate to a set of online retailers.
  • the entities and workflows relate to a set of ecommerce sites. In embodiments, the entities and workflows relate to a set of demand factors. In embodiments, the entities and workflows relate to a set of supply factors. In embodiments, the entities and workflows relate to a set of delivery systems.
  • the entities and workflows relate to a set of floating assets. In embodiments, the entities and workflows relate to a set of points of origin. In embodiments, the entities and workflows relate to a set of points of destination. In embodiments, the entities and workflows relate to a set of points of storage.
  • the entities and workflows relate to a set of points of product usage. In embodiments, the entities and workflows relate to a set of networks. In embodiments, the entities and workflows relate to a set of information technology systems. In embodiments, the entities and workflows relate to a set of software platforms.
  • the entities and workflows relate to a set of distribution centers. In embodiments, the entities and workflows relate to a set of fulfillment centers. In embodiments, the entities and workflows relate to a set of containers. In embodiments, the entities and workflows relate to a set of container handling facilities.
  • the entities and workflows relate to a set of customs. In embodiments, the entities and workflows relate to a set of export control. In embodiments, the entities and workflows relate to a set of border control. In embodiments, the entities and workflows relate to a set of drones.
  • the entities and workflows relate to a set of robots. In embodiments, the entities and workflows relate to a set of autonomous vehicles. In embodiments, the entities and workflows relate to a set of hauling facilities. In embodiments, the entities and workflows relate to a set of drones, robots and autonomous vehicles. In embodiments, the entities and workflows relate to a set of waterways. In embodiments, the entities and workflows relate to a set of port infrastructure facilities.
  • the set of digital twins may include, for example and without limitation, distribution twins, warehousing twins, port infrastructure twins, shipping facility twins, operating facility twins, customer twins, worker twins, wearable device twins, portable device twins, mobile device twins, process twins, machine twins, asset twins, product twins, point of origin twins, point of destination twins, supply factor twins, maritime facility twins, floating asset twins, shipyard twins, fulfillment twins, delivery system twins, demand factors twins, retailer twins, ecommerce twins, online twins, waterway twins, roadway twins, roadway twins, railway twins, air facility twins, aircraft twins, ship twins, vehicle twins, train twins, autonomous vehicle twins, robotic system twins, drone twins, logistics factor twins and many others.
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 614 , a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a set of microservices layers including an application layer supporting at least one supply chain application and at least one demand management application, wherein the applications of the application layer use a common set of services among a set of data processing services, data collection services, and data storage services.
  • the VCNP 604 may further include a set of microservices layers including an application layer supporting at least two applications among a set of demand management applications 1502 , a set of supply chain applications 1500 , a set of intelligent product applications 1510 , a set of asset management applications 1530 and a set of enterprise resource management applications 1520 for a category of goods.
  • a microservices architecture provides several advantages to the platform 604 .
  • one advantage may be the ability to leverage creation of improved microservices created by others such that developer may only need to define inputs and outputs such that the platform may use readily adapted services created by others.
  • use of the microservices architecture may provide ability to modularize microservices into collections that may be used to achieve tasks. For example, a goal to determine what is happening in a warehouse may be achieved with a variety of microservices with minimal cost such as vision-based service, series of regular prompts that may ask and receive, reading off of event logs or feeds, and the like. Each one of these microservices may be a distinct microservice that may be easily plugged in and used.
  • microservice may be replaced easily with another service with minimal impact to other components in the platform.
  • Other microservices include recommendation service, collaborative filtering service, deep learning with semi-supervised learning service, etc.
  • the microservice architecture may provide modularity at each stage in building a full workflow.
  • a microservice may be built for multiple applications that may be consumed including shared data steam and anything else enabled by the microservices architecture.
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 1160 , a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a set of microservices layers including an application layer supporting at least one supply chain application and at least one demand management application, wherein the microservice layers include a data collection layer that collects information from a set of Internet of Things resources that collect information with respect to supply chain entities and demand management entities.
  • Also provided herein are methods, systems, components and other elements for an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a machine learning/artificial intelligence system configured to generate recommendations for placing an additional sensor/and or camera on and/or in proximity to a value chain entity and wherein data from the additional sensor and/or camera feeds into a digital twin that represents a set of value chain entities.
  • the VCNP 604 may further include a set of microservices, wherein the microservice layers include a monitoring systems and data collections systems layer 614 having data collection and management systems 640 that collect information from a set of Internet of Things resources 1172 that collect information with respect to supply chain entities and demand management entities 652 .
  • the microservices may support various applications among a set of demand management applications 1502 , a set of supply chain applications 1500 , a set of intelligent product applications 1510 , a set of asset management applications 1530 and a set of enterprise resource management applications 1520 for a category of goods.
  • the platform 604 may further include a machine learning/artificial intelligence system 1160 that includes a sensor recommendation system 1750 that is configured to generate recommendations for placing an additional sensor 1462 and/or camera on and/or in proximity to a value chain network entity 652 .
  • the sensor recommendation system 1750 may generate recommendations by using load, array of signals, emergent situations, frequency response, maintenance, diagnosis, etc.
  • Data from the additional sensor 1462 and/or camera may feed into a digital twin 1700 that represents a set of value chain entities 652 .
  • the set of Internet of Things resources that collect information with respect to supply chain entities and demand management entities collects information from entities of any of the types described throughout this disclosure and in the documents incorporated by reference herein.
  • the set of Internet of Things resources may be of a wide variety of types such as, without limitation, camera systems, lighting systems, motion sensing systems, weighing systems, inspection systems, machine vision systems, environmental sensor systems, onboard sensor systems, onboard diagnostic systems, environmental control systems, sensor-enabled network switching and routing systems, RF sensing systems, magnetic sensing systems, pressure monitoring systems, vibration monitoring systems, temperature monitoring systems, heat flow monitoring systems, biological measurement systems, chemical measurement systems, ultrasonic monitoring systems, radiography systems, LIDAR-based monitoring systems, access control systems, penetrating wave sensing systems, SONAR-based monitoring systems, radar-based monitoring systems, computed tomography systems, magnetic resonance imaging systems, network monitoring systems, or others.
  • types such as, without limitation, camera systems, lighting systems, motion sensing systems, weighing systems, inspection systems, machine vision systems, environmental sensor systems, onboard sensor systems, onboard diagnostic systems, environmental control systems, sensor-enabled network switching and routing systems, RF sensing systems, magnetic sensing systems, pressure monitoring systems, vibration monitoring systems, temperature monitoring
  • the set of Internet of Things resources includes a set of camera systems. In embodiments, the set of Internet of Things resources includes a set of lighting systems. In embodiments, the set of Internet of Things resources includes a set of machine vision systems. In embodiments, the set of Internet of Things resources includes a set of motion sensing systems.
  • the set of Internet of Things resources includes a set of weighing systems. In embodiments, the set of Internet of Things resources includes a set of inspection systems. In embodiments, the set of Internet of Things resources includes a set of environmental sensor systems. In embodiments, the set of Internet of Things resources includes a set of onboard sensor systems.
  • the set of Internet of Things resources includes a set of onboard diagnostic systems. In embodiments, the set of Internet of Things resources includes a set of environmental control systems. In embodiments, the set of Internet of Things resources includes a set of sensor-enabled network switching and routing systems. In embodiments, the set of Internet of Things resources includes a set of RF sensing systems. In embodiments, the set of Internet of Things resources includes a set of magnetic sensing systems.
  • the set of Internet of Things resources includes a set of pressure monitoring systems. In embodiments, the set of Internet of Things resources includes a set of vibration monitoring systems. In embodiments, the set of Internet of Things resources includes a set of temperature monitoring systems. In embodiments, the set of Internet of Things resources includes a set of heat flow monitoring systems. In embodiments, the set of Internet of Things resources includes a set of biological measurement systems.
  • the set of Internet of Things resources includes a set of chemical measurement systems. In embodiments, the set of Internet of Things resources includes a set of ultrasonic monitoring systems. In embodiments, the set of Internet of Things resources includes a set of radiography systems. In embodiments, the set of Internet of Things resources includes a set of LIDAR-based monitoring systems. In embodiments, the set of Internet of Things resources includes a set of access control systems.
  • the set of Internet of Things resources includes a set of penetrating wave sensing systems. In embodiments, the set of Internet of Things resources includes a set of SONAR-based monitoring systems. In embodiments, the set of Internet of Things resources includes a set of radar-based monitoring systems. In embodiments, the set of Internet of Things resources includes a set of computed tomography systems. In embodiments, the set of Internet of Things resources includes a set of magnetic resonance imaging systems. In embodiments, the set of Internet of Things resources includes a set of network monitoring systems.
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 1160 , a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a set of microservices layers including an application layer supporting at least one supply chain application and at least one demand management application, wherein the microservice layers include a data collection layer that collects information from a set of social network sources that provide information with respect to supply chain entities and demand management entities.
  • the VCNP 604 may further include a set of microservices layers that include a data collection layer (e.g., monitoring systems and data collection systems layer 614 ) with a social data collection facility 1760 that collects information from a set of social network resources MPVC 1708 that provide information with respect to supply chain entities and demand management entities.
  • the social network data collection facilities 1760 may support various applications among a set of demand management applications 1502 , a set of supply chain applications 1500 , a set of intelligent product applications 1510 , a set of asset management applications 1530 and a set of enterprise resource management applications 1520 for a category of goods.
  • Social network data collection (using social network data collection facilities 1760 ) may be facilitated by a social data collection configuration interface, such as for configuring queries, identifying social data sources of relevance, configuring APIs for data collection, routing data to appropriate applications 630 , and the like.
  • a social data collection configuration interface such as for configuring queries, identifying social data sources of relevance, configuring APIs for data collection, routing data to appropriate applications 630 , and the like.
  • the platform 604 may employ a micro-services architecture with the various data handling layers 608 , a set of network connectivity facilities 642 (which may include or connect to a set of interfaces 702 of various layers of the platform 604 ), a set of adaptive intelligence facilities or adaptive intelligent systems 1160 , a set of data storage facilities or systems 624 , and a set of monitoring facilities or systems 808 .
  • the platform 604 may support a set of applications 614 (including processes, workflows, activities, events, use cases and applications) for enabling an enterprise to manage a set of value chain network entities 652 , such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • applications 614 including processes, workflows, activities, events, use cases and applications
  • a set of value chain network entities 652 such as from a point of origin to a point of customer use of a product 1510 , which may be an intelligent product.
  • an information technology system may include: a cloud-based management platform with a micro-services architecture, a set of interfaces, network connectivity facilities, adaptive intelligence facilities, data storage facilities, and monitoring facilities that are coordinated for monitoring and management of a set of value chain network entities; a set of applications for enabling an enterprise to manage a set of value chain network entities from a point of origin to a point of customer use; and a set of microservices layers including an application layer supporting at least one supply chain application and at least one demand management application, wherein the microservice layers include a data collection layer that collects information from a set of crowdsourcing resources that provide information with respect to supply chain entities and demand management entities.
  • the VCNP 604 may further include a set of microservices layers that include a monitoring systems and data collection systems layer 614 with a crowdsourcing facility 1770 that collects information from a set of crowdsourcing resources that provide information with respect to supply chain entities and demand management entities.
  • the crowdsourcing facilities 1770 may support various applications among a set of demand management applications 1502 , a set of supply chain applications 1500 , a set of intelligent product applications 1510 , a set of asset management applications 1530 and a set of enterprise resource management applications 1520 for a category of goods.
  • Crowdsourcing may be facilitated by a crowdsourcing interface, such as for configuring queries, setting rewards for information, configuring workflows, determining eligibility for participation, and other elements of crowdsourcing.
  • the digital twins 1700 are configured to simulate properties, states, operations, behaviors and other aspects of the value chain network entities 652 .
  • the digital twins 1700 may have a visual user interface, e.g., in the form of 3D models, or may consist of system specifications or ontologies describing the architecture, including components and their interfaces, of the value chain network entities 652 .
  • the digital twins 1700 may include configuration or condition of the value chain network entities 652 , including data records of the past and current state of the value chain network entities 652 , such as captured through sensors, through user input, and/or determined by outputs of behavioral models that describe the behavior of the value chain network entities 652 .
  • the digital twins 1700 may be updated continuously to reflect the current condition of the value chain network entities 652 , based on sensor data, test and inspection results, conducted maintenance, modifications, etc.
  • the digital twins 1700 may also be configured to communicate with a user via multiple communication channels, such as speech, text, gestures, and the like. For example, a digital twin 1700 may receive queries from a user about the value chain network entities 652 , generate responses for the queries, and communicate such responses to the user.
  • digital twins 1700 may communicate with one another to learn from and identify similar operating patterns and issues in other value chain network entities 652 , as well as steps taken to resolve those issues.
  • the digital twins 1700 may be used for monitoring, diagnostics, simulation, management, remote control, and prognostics, such as to optimize the individual and collective performance and utilization of value chain network entities 652 .
  • machine twins 21010 may continuously capture the key operational metrics of the machines 724 and may be used to monitor and optimize machine performance in real time.
  • Machine twins 21010 may combine sensor, performance, and environmental data, including insights from similar machines 724 , enabling prediction of life span of various machine components and informed maintenance decisions.
  • machine twins 21010 may generate an alert or other warning based on a change in operating characteristics of the machine 724 . The alert may be due to an issue with a component of the machine 724 .
  • machine twins 21010 may determine similar issues that have previously occurred with the machine or similar machines, provide a description of what caused the issues, what was done to address the issues, and explain differences between the present issue and the previous issues and what actions to take to resolve the issue, etc.
  • warehousing twins 1712 may combine a 3D model of the warehouse with inventory and operational data including the size, quantity, location, and demand characteristics of different products.
  • the warehousing twins 1712 may also collect sensor data in a connected warehouse, as well as data on the movement of inventory and personnel within the warehouse. Warehousing twins 1712 may help in optimizing space utilization and aid in identification and elimination of waste in warehouse operations.
  • the simulation using warehousing twins 1712 of the movement of products, personnel, and material handling equipment may enable warehouse managers to test and evaluate the potential impact of layout changes or the introduction of new equipment and new processes.
  • multiple digital twins of the value chain network entities 652 may be integrated, thereby aggregating data across the value chain network to drive not only entity-level insights but also system-level insights.
  • the operating facility digital twin 1172 may need to integrate the data from digital twins 1770 of different machines to get a holistic picture of the complete conveyor line in the operating facility 712 (e.g., a warehouse, distribution center, or fulfillment center where packages are moved along a conveyor and inspected before being sent out for delivery. While the digital twin of conveyor line may provide insights about only its performance, the composite digital twin may aggregate data across the different machines in the operating facility 712 .
  • the supply factor twins 1650 and demand factor twins 1640 may be integrated to create a holistic picture of demand-supply equilibrium for a product 1510 .
  • the integration of digital twins also enables the querying of multiple value chain network entities 652 and create a 360-degree view of the value chain network 668 and its various systems and subsystems.
  • a machine digital twin 1770 is comprised of multiple digital twins of sub-systems and individual components constituting the machine 724 .
  • the machine's digital twin may integrate all such component twins and their inputs and outputs to build the model of the machine.
  • a distribution facility twins system 1714 may be comprised of subsystems, such as warehousing twins 1712 , fulfilment twins 1600 and delivery system twins 1610 .
  • the process digital twin may be seen as comprised of digital twins of multiple sub-processes representing entities selected from among supply chain entities, demand management entities and value chain network entities.
  • the digital twin of a packaging process is comprised of digital twins of sub-processes for picking, moving, inspecting and packing the product.
  • the digital twin of warehousing process may be seen as comprised of digital twins of multiple sub-processes including receiving, storing, picking and shipping of stored inventories.
  • a value chain network digital twin system may be generated from a plurality of digital twin subsystems or conversely a digital twin subsystem may be generated from a digital twin system, wherein at least one of the digital twin subsystem and the digital twin system represents entities selected from among supply chain entities, demand management entities and value chain network entities.
  • a value chain network digital twin process may be generated from a plurality of digital twin sub-processes or conversely digital twin sub-process generated from a digital twin process wherein at least one of the digital twin sub-process and the digital twin process represents entities selected from among supply chain entities, demand management entities and value chain network entities.
  • the analytics obtained from digital twins 1700 of the value chain network entities 652 and their interactions with one another provide a systemic view of the value chain network as well as its systems, sub-systems, processes and sub-processes. This may help in generating new insights into ways the various systems and processes may be evolved to improve their performance and efficiency.
  • the platform 604 and applications 630 may have a system for generating and updating a self-expanding digital twin that represents a set of value chain entities.
  • the self-expanding digital twin continuously keeps learning and expanding in scope, with more and more data it collects and scenarios it encounters. As a result, the self-expanding twin can evolve with time and take on more complex tasks and answer more complex questions posed by a user of the self-expanding digital twin.
  • the platform 604 and applications 630 may have a system for scheduling the synchronization of a physical value chain entity's changing condition to a digital twin that represents a set of value chain entities.
  • the synchronization between the physical value chain entity and its digital twin is on a near real-time basis.
  • the platform 604 and applications 630 may have an application programming interface for extracting, sharing, and/or harmonizing data from information technology systems associated with multiple value chain network entities that contribute to a single digital twin representing a set of value chain entities.
  • value chain network management platform 604 may include various subsystems that may be implemented as micro services, such that other subsystems of the system access the functionality of a subsystem providing a micro service via application programming interface API.
  • the various services that are provided by the subsystems may be deployed in bundles that are integrated, such as by a set of APIs.
  • value chain network management platform 604 may include a set of microservices for managing a set of value chain network entities for an enterprise and having a set of processing capabilities for at least one of creating, modifying, and managing the parameters of a digital twin that is used in the platform to represent a set of value chain network entities.
  • the value chain network management platform may provide a digital twin sub-system in the form of an out-of-the-box kit system with self-configuring capabilities.
  • the kit may provide a data-rich and interactive overview of a set of value chain network entities constituting the sub-system.
  • a supply chain out-of-the-box digital twin kit system may represent a set of supply chain entities that are linked to the identity of an owner or operator of the supply chain entities. The owner or operator of the supply chain entity may then use the kit to get a holistic picture of its complete portfolio. The owner may investigate for information related to various supply chain entities and ask interactive questions from the digital twin kit system.
  • a demand management out-of-the-box digital twin kit system may represent a set of demand management entities that are linked to the identity of an owner or operator of the demand management entities.
  • a value chain network digital twin kit system for providing out-of-the-box, self-configuring capabilities may represent a set of demand management entities and a set of supply chain entities that are linked to the identity of an owner or operator of the demand management entities and the supply chain entities.
  • a warehouse digital twin kit system for providing out-of-the-box, self-configuring capabilities may represent a set of warehouse entities that are linked to the identity of an owner or operator of the warehouse.
  • the warehouse digital twin kit system 5000 includes warehousing twins in the virtual space 5002 representing models of warehouses 654 in the real space 5004 .
  • the warehouse digital twin kit system 5000 allows an owner or operator 5008 of the one or more warehouse entities 654 to get complete portfolio overview of all these entities—existing or in design or construction.
  • the owner 5008 may navigate a wealth of information including warehouse photographs 5010 , 3D images 5012 , live video feeds 5014 of real-time construction progress and AR or VR renderings 5018 of the warehousing entities 654 .
  • the owner 5008 may investigate about the health of one or more entities 654 and ask interactive questions and search for detailed information about one or more warehouse entities 654 .
  • the warehouse digital twin kit system 5000 has access to real time dynamic data captured by IoT devices and sensors at warehouse entities 654 and may be supported with natural language capabilities enabling it to interact with the owner 5008 and answer any questions about the condition of the warehouse entities 654 .
  • warehouse digital twin kit system 5000 may provide the portfolio overview of warehouse entities 654 to owner 5008 in the form of a 3D information map containing all the warehouse entities 654 .
  • Owner 5008 may select a specific entity on the map and get information about inventory, operational and health data from the warehousing twin 1710 . Alternatively, the owner 5008 may ask for information about the overall portfolio of warehouse entities 654 owned.
  • the warehouse digital twin kit system 5000 consolidates information from the multiple warehousing twins 1710 and provides a holistic view. The consolidated view may help owner 5008 to optimize operations across warehouse entities 654 by adjusting stock locations and staffing levels to match current or forecasted demand.
  • the owner 5008 may also display the information from warehouse digital twin kit system 5000 on a website or marketing material to be accessed by any customers, suppliers, vendors and other partners.
  • a container ship digital twin kit system for providing out-of-the-box, self-configuring capabilities may represent a set of container ship entities that are linked to the identity of an owner or operator of the container ship.
  • a port infrastructure digital twin kit system for providing out-of-the-box, self-configuring capabilities may represent a set of port infrastructure entities that are linked to the identity of an owner or operator of the port infrastructure.
  • the platform 604 may deploy digital twins 1700 of value chain network entities 652 for testing the compatibility between different value chain network entities 652 interacting with one another and forming various systems and subsystems of the value chain network.
  • the digital twin 1700 may make use of artificial intelligence systems 1160 (including any of the various expert systems, artificial intelligence systems, neural networks, supervised learning systems, machine learning systems, deep learning systems, and other systems described throughout this disclosure and in the documents incorporated by reference) for carrying out the compatibility testing in the value chain network.
  • artificial intelligence systems 1160 including any of the various expert systems, artificial intelligence systems, neural networks, supervised learning systems, machine learning systems, deep learning systems, and other systems described throughout this disclosure and in the documents incorporated by reference
  • the platform may provide a system for testing compatibility or configuration of a set of vendor components for a container ship using a set of digital twins representing the container ship and the vendor components.
  • the platform may provide a system for testing compatibility or configuration of a set of vendor components for a warehouse using a set of digital twins representing the warehouse and the vendor components.
  • the platform may provide a system for testing compatibility or configuration of a set of vendor components for a port infrastructure facility using a set of digital twins representing the port infrastructure facility and the vendor components.
  • the platform may provide a system for testing compatibility or configuration of a set of vendor components for a shipyard facility using a set of digital twins representing the shipyard facility and the vendor components.
  • the platform may provide a system for testing compatibility or configuration of a container ship and a set of port infrastructure facilities using a set of digital twins representing the container ship and the port infrastructure facility.
  • the platform may provide a system for testing compatibility or configuration of a barge and a set of waterways for a navigation route using a set of digital twins representing the barge and the set of waterways.
  • the platform may provide a system for testing compatibility or configuration of a container ship and a set of cargo for an identified shipment using a set of digital twins representing the container ship and the cargo.
  • the platform may provide a system for testing compatibility or configuration of a barge and a set of cargo for an identified shipment using a set of digital twins representing the barge and the cargo.
  • the platform may provide a system for testing compatibility or configuration of a set of cargo handling infrastructure facilities and a set of cargo for an identified shipment using a set of digital twins representing the cargo handling infrastructure facilities and the cargo.
  • the platform 604 may deploy digital twins 1700 of value chain network entities 652 to perform stress tests on a set of value chain network entities.
  • the digital twins may help simulate behavior of value chain network systems and sub-systems in a wide variety of environments.
  • the stress tests may help run any “what-if” scenarios to understand the impact of change in relevant parameters beyond normal operating values and evaluate the resilience of the infrastructure of value chain network.
  • the platform 604 may include a system for learning on a training set of outcomes, parameters, and data collected from data sources relating to a set of value chain network activities to train artificial intelligence systems 1160 (including any of the various expert systems, artificial intelligence systems, neural networks, supervised learning systems, machine learning systems, deep learning systems, and other systems described throughout this disclosure and in the documents incorporated) for performing such stress tests on the value chain network.
  • artificial intelligence systems 1160 including any of the various expert systems, artificial intelligence systems, neural networks, supervised learning systems, machine learning systems, deep learning systems, and other systems described throughout this disclosure and in the documents incorporated
  • the platform may include a system for learning on a training set of machine outcomes, parameters, and data collected from data sources relating to a set of value chain network activities to train an artificial intelligence/machine learning system to perform stress tests on the machine using a digital twin that represents a set of value chain entities.
  • the value chain network comprises a plurality of interrelated sub-systems and sub-processes that manage and control all aspects associated with the production and delivery of a finished product to an end-user—from the acquisition and distribution of raw materials between a supplier and a manufacturer, through the delivery, distribution, and storage of materials for a retailer or wholesaler, and, finally, to the sale of the product to an end-user.
  • the complex interconnected nature of the value chain network means that an adverse event within one subsystem or one or more value chain entities reflect through the entire value chain network.
  • FIG. 54 is an example method for performing a stress test on the value chain network.
  • the stress test may comprise a simulation exercise to test the resilience of the value chain network (including its subsystems) and determine its ability to deal with an adverse scenario, say a natural calamity, a congested route, a change in law, or a deep economic recession.
  • adverse or stress scenarios may affect one or more entities or subsystems within the value chain network depending on the nature of the scenario.
  • any stress tests would require simulating scenarios and analyzing the impact of different scenarios across different subsystems and on the overall value chain network.
  • the data may include information related to various operating parameters of the value chain network over a particular historical time period, say last 12 months.
  • the data may also provide information on the typical values of various operating parameters under normal conditions. Some examples of operating parameters include: product demand, procurement lead time, productivity, inventory level at one or more warehouses, inventory turnover rates, warehousing costs, average time to transport product from warehouse to shipping terminals, overall cost of product delivery, service levels, etc.
  • one or more simulation models of value chain network are created based on the data. The simulation models help in visualizing the value chain network as a whole and in predicting how changes in operating parameters affect the operation and performance of the value chain network.
  • the simulation model may be a sum of multiple models of different subsystems of the value chain network.
  • one or more stress scenarios may be simulated by changing one or more parameters beyond the normal operating values.
  • the simulating of stress scenarios overcome the limitation of any analysis based only on historical data and helps analyze the network performance across a range of hypothetical yet plausible stress conditions.
  • the simulation involves varying (shocking) one or more parameters while keeping the other parameters as fixed to analyze the impact of such variations on value chain network.
  • a single parameter may be varied while keeping remaining parameters as fixed.
  • multiple parameters may be varied simultaneously.
  • the outcomes of stress scenario simulations are determined, and the performance of value chain network and its different subsystems is estimated across various scenarios.
  • the data, parameters and outcomes are fed into a machine learning process in the artificial intelligence system 1160 for further analysis.
  • the platform may include a system for learning on a training set of outcomes, parameters, and data collected from data sources relating to a set of value chain network activities to train an artificial intelligence/machine learning system to perform stress tests on a physical object using a digital twin that represents a set of value chain entities.
  • the platform may include a system for learning on a training set of outcomes, parameters, and data collected from data sources relating to a set of value chain network activities to train an artificial intelligence/machine learning system to perform stress tests on a telecommunications network using a digital twin that represents a set of value chain entities in a connected network of entities and the telecommunications network.
  • the telecommunications network may be stress tested for resiliency by deliberately increasing network traffic by generating and sending data packets to a specific target node within the telecommunications network. Further, the amount of traffic may be varied to create varying load conditions on the target node by manipulating the number, rate or amount of data in the data packets. The response from the target node may be determined to evaluate how the node performed in the stress test. The target node may be selected at different parts of the telecommunications network for stress testing so as to test robustness of any portion of the network in any topology. The simulated stress tests on the telecommunications network may be utilized to identify vulnerabilities in any portion of a network so that the vulnerability can be rectified before users experience network outages in a deployed network.
  • the platform may include a system for using a digital twin that represents a set of value chain entities in a demand management environment to perform a set of stress tests on a set of workflows in the demand management environment using the digital twin, wherein the stress tests represent impacts in the digital twin of varying a set of demand-relevant parameters to levels that exceed normal operating levels.
  • the demand of a product in the value chain network may be affected by factors like changes in consumer confidence, recessions, excessive inventory levels, substitute product pricing, overall market indices, currency exchange changes, etc.
  • the demand factors twin 1640 may simulate such scenarios by varying supply parameters and evaluate the impact of such stresses on the demand environments 672 .
  • the stress tests performed using the digital twins may help in testing and evaluating the resiliency of the value chain network both in cases of over-demand and under-demand.
  • the platform may include a system for using a digital twin that represents a set of value chain entities in the supply chain to perform a set of stress tests on a set of workflows in the supply chain using the digital twin, wherein the stress tests represent impacts in the digital twin of varying a set of supply chain-relevant parameters to levels that exceed normal operating levels.
  • the supply of a product in the value chain network may be affected by factors like weather, natural calamities, traffic congestion, regulatory changes including taxes and subsidies and border restrictions, etc.
  • the supply factors twin 1650 may simulate such scenarios by varying supply parameters and evaluate the impact of such stresses on the supply environments 670 .
  • the stress tests performed using the digital twins may help in testing and evaluating the resiliency of the value chain network both in cases of over-supply and under-supply.
  • the platform 604 may deploy digital twins 1700 of value chain network entities 652 for automatically managing a set of incidents relating to a set of value chain network entities and activities.
  • the incidents may include any events causing disruption to the value chain network like accidents, fires, explosions, labor strikes, increases in tariffs, changes in law, changes in market prices (e.g., of fuel, components, materials, or end products), changes in demand, activities of cartels, closures of borders or routes, and/or natural events and/or disasters (including storms, heat waves, winds, earthquakes, floods, hurricanes, tsunamis, etc.), among many others.
  • the platform 604 may provide real-time visualization and analysis of mobility flows in the value chain network. This may help in quantifying risks, improving visibility and reacting to the disruptions in the value chain network.
  • real-time visualization of a utility flow for shipping activities using a digital twin may help in detecting the occurrence and location of an emergency involving a shipping system and deploying emergency services to the detected location.
  • the platform may deploy digital twins 1700 of value chain network entities 652 for more accurate determination of accident fault.
  • the platform may learn on a training set of accident outcomes, parameters, and data collected from the monitoring layer 614 and data sources of the data storage layer 624 to train artificial intelligence system 1160 using a set of digital twins 1700 of involved value chain network entities 652 to determine accident fault. For example, data from digital twins of two colliding vehicles may be compared with each other in addition to data from the drivers, witnesses and police reports to determine accident fault.

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