DE102021211828A1 - Computer-implemented method to support planning and organization of a construction project, device for data processing as part of such a method, and computer program for implementing such a method - Google Patents

Abstract

A computer-implemented method for supporting planning and organization of a construction project by extracting information from at least one construction document (12a, 14a) relating to the construction project is proposed, comprising the method steps:
• Providing, in particular recording, the content of at least one learning document (18a, 20a) which documents at least one completed old project,
• learning a meaning of the content of the learning document (18a, 20a) using machine learning (22a),
• Providing, in particular recording, a content of the construction document (12a, 14a),
• Assess the construction project by applying the learned meaning to the content of the construction document (12a, 14a) and
• Output of an analysis (24a, 26a) of the construction project created in the course of the evaluation.

Description

State of the art

In order to support the planning and organization of a construction project, the general contractor (GU) and his subcontractors (SU) usually use company-specific digital administrative processes in the construction industry. Data is usually exchanged using paper data or individual file formats, which are read in separately at the other company, so that data from different systems is exchanged. In particular, this means that a great deal of effort can be required to extract desired information from all of this data and to have it available in a structured form.

Disclosure of Invention

• • Bereitstellen, insbesondere Erfassen, eines Inhalts zumindest eines Lerndokuments, welches zumindest ein abgeschlossenes Altprojekt dokumentiert;
• • Erlernen einer Bedeutung des Inhalts des Lerndokuments mittels maschinellen Lernens;
• • Bereitstellen, insbesondere Erfassen, eines Inhalts des Baudokuments;
• • Bewerten des Bauprojekts durch Anwendung der erlernten Bedeutung auf den Inhalt des Baudokuments und Ausgabe einer im Zuge des Bewertens erstellten Analyse des Bauprojekts.

A computer-implemented method for supporting planning and organization of a construction project by extracting information from at least one construction document relating to the construction project is proposed, which comprises the following method steps:

• • Providing, in particular recording, the content of at least one learning document which documents at least one completed old project;
• • learning a meaning of the content of the learning document using machine learning;
• • Providing, in particular recording, a content of the construction document;
• • Assess the construction project by applying the learned meaning to the content of the construction document and outputting an analysis of the construction project generated during the assessment.

The method is intended in particular to evaluate a large number of construction documents, in particular from different sources, in order to create the analysis of the construction project. Examples of the at least one construction document include in particular an invoice, a delivery note, an official letter, an expert opinion, a construction plan, documentation of construction progress, a presentation, a certification certificate, a holiday and/or shift plan, a technical data sheet, a floor plan, a schedule, resource list or other documents that arise in connection with the planning and/or execution of the construction project. The at least one construction document is in particular a digital or physical document and/or a digital or physical drawing. The at least one construction document can also be in the form of a photo, video recording, voice recording or the like. Sources for the at least one construction document include, for example, a general contractor for the construction project, a subcontractor involved in the construction project, a supplier for the construction project, an authority, an external appraiser, a bank, a lawyer, a client of the construction project, a resident, a buyer or something.

The legacy project is in particular a construction project that is different from the construction project. The old project is preferably a project in the past in relation to the construction project. The legacy project may have been successfully completed, in particular within a timeframe and/or within a budget of the legacy project, completed at increased cost and/or time, or, particularly at any stage of construction, abandoned. In particular, the at least one learning document of the old project is a document that is analogous to the at least one construction document of the construction project to be analyzed and that arose as part of the old project. In particular, the above examples of the at least one construction document are also examples of the at least one learning document. Preferably, for learning the meaning of the content of the at least one learning document, in particular additionally, a final report of the old project is provided as a learning document, in particular recorded. In order to learn the meaning of the content of the at least one learning document, learning documents from a number of old projects are particularly preferably provided, in particular recorded.

The method is preferably carried out by a data processing device which in particular comprises at least one processor unit, at least one memory unit, at least one input unit and at least one output unit. When the at least one construction document and/or the at least one learning document is provided, the at least one construction document and/or the at least one learning document is stored in particular in the storage unit. The at least one construction document and/or the at least one learning document can be provided by an operator of the data processing device using the input unit, in particular by transferring the at least one construction document and/or the at least one learning document from an external storage medium and/or an external data network. Additionally or alternatively, the processor unit retrieves the at least one construction document and/or the at least one learning document automatically, for example from an e-mail program of the data processing device, from an external data network, from a cloud service or the like. An operator can optionally create the at least one learning document and/or the at least one construction document using the data processing device. If the at least one construction document and/or the at least one training document is on a non-electronic storage medium, in particular on paper, photographic paper, writing film or the like, the at least one training document and/or the at least one construction document is preferably digitized, for example using a Scanner, a digital camera, a fax machine or the like and transmitted to the data processing device manually or automatically. If several learning documents and/or several building documents are stored in the storage unit, the learning documents and/or building documents can each be stored as an independent file or can be stored together in one file. In particular, the term "document" refers to a contentual unit of meaning, in particular in contrast to a "file", which can be an unit used by the data processing device for storing a portion of a document, the entire document or multiple documents.

The processor unit preferably uses pattern recognition routines in order to record the content of the at least one learning document and/or the at least one construction document, which is stored in particular in the memory unit. The pattern recognition routines include, in particular, text recognition, image recognition and/or speech recognition, which are implemented in particular using methods known from the prior art. Text recognition can in particular include recognition of machine-made text and/or handwritten text. Image recognition can in particular include simple geometric figures such as lines, circles, rectangles, arrows or the like, composite figures such as company logos and/or signatures and/or complex figures, in particular objects within a photo or the like. In particular, the processor unit captures content objects that make up the content of the at least one construction document and/or the at least one learning document, such as a block of text, a date, a diagram, a table, an image, a sketch, a handwritten note or the like. The processor unit preferably also records at least one property of the recorded content object, for example a size, a font, a highlight, a color, an orientation and/or position within the at least one construction document and/or the at least one learning document, a position relative to another content object or the like. Before using the pattern recognition, the processor unit preferably checks whether the content of the at least one construction document stored in the memory unit and/or the at least one learning document can be read out directly. The content of the at least one construction document and/or the at least one training document can be read out directly, for example, if the at least one construction document and/or the at least one training document is in a data format of a word processing program, a graphics program, a spreadsheet program or a specific planning program known to the processor unit and creation of floor plans, building installations, circuit diagrams or the like. The processor unit preferably skips an application of the pattern recognition routines if the content of the construction document and/or the at least one learning document can be read out directly. The processor unit uses the read out and/or recognized content, in particular the content objects and optionally their properties, of the at least one learning document as input data for the machine learning. The processor unit uses the read and/or recognized content, in particular the content objects and optionally their properties, of the at least one construction document as input data for evaluating the construction project.

The machine learning and the assessment of the construction project is preferably carried out using at least one, in particular multi-layer, artificial neural network, which is implemented on the data processing device. The artificial neural network can be designed, for example, as a convolutional neural network (CNN), as a recurrent neural network (RNN) or as a neural network with transformer architecture. In particular, the processor unit feeds the content, in particular the content objects and optionally their properties, of the at least one learning document and/or the at least one construction document to an input layer of the artificial neural network. The artificial neural network preferably learns at least one meaning element of the at least one learning document through machine learning. In particular, when evaluating the construction project, the artificial neural network attempts to recognize the at least one learned meaning element in the at least one construction document. The meaning element can in particular be a header element which the artificial neural network tries to recognize in every available construction document, or a specific meaning element which depends in particular on a document type of the construction document. The above examples of the at least one construction document are in particular examples of different document types. For example, header elements include the document type of construction document, the source of the construction document, a recipient of the construction document, a date, in particular a creation date and/or a receipt date, of the construction document or other elements of meaning. For example, for an invoice as a construction document, specific meaning elements include a performance date, an invoice item with an amount, a total amount, or the like. The artificial neural network outputs the at least one recognized meaning element in particular to an output layer or an intermediate layer of the artificial neural network.

The processor unit preferably feeds the at least one recognized meaning element, in particular a large number of recognized meaning elements, of the construction document, in particular from a large number of construction documents, to an input layer of a further artificial neural network of the data processing device or to a further input layer of the artificial neural network in order to analyze the construction project to create. In particular, the artificial neural network or the further artificial neural network is provided to identify at least one connection between two different construction documents in order to create the analysis. The analysis of the construction project can in particular include an assessment of the status of the construction project at the time the method is carried out, in particular at a time of the construction document that has the most recent date, and/or a prognosis of a status of the construction project. In particular, the analysis includes a target parameter that evaluates the construction project. The target parameter is, for example, a required amount of material, a required amount of money, additional costs compared to the originally estimated costs, construction progress, a deviation from an originally estimated schedule or the like. The target parameter is preferably output when the construction project is evaluated by the artificial neural network at a further output layer of the artificial neural network or by the further artificial neural network at an output layer of the further artificial neural network. In particular, the artificial neural network and/or the further artificial neural network is trained in machine learning to determine the target parameter from the at least one meaning element. During the machine learning, the target parameter is preferably specified by a user of the method who is monitoring the machine learning. In particular, the user assigns the at least one target parameter to the at least one learning document, for example by preparing the at least one learning document, in particular by attaching a note to the at least one learning document in physical and/or digital form and/or by creating a list stored in the storage unit , in which a value of the target parameter is assigned to each learning document. The analysis, in particular the at least one target parameter, is preferably output using the output unit and/or stored in the storage unit.

As a result of the configuration according to the invention, the effort involved in organizing a large number of construction documents can advantageously be kept low, and in particular costs can advantageously be saved. In particular, information from different sources can advantageously be easily exchanged using an advantageously standardized and digital method. In particular, information obtained from the construction documents can advantageously be processed and stored in a structured and networked manner. In particular, a coordination of stakeholders involved in the construction project, in particular a coordination of subcontractors, can advantageously be easily organized before and during the construction project. In addition, construction documents can be digitized into a machine-understandable and advantageously standardized form. Furthermore, a largely complete management of the construction project can advantageously be achieved easily. In particular, possible errors in the planning and/or execution of the construction project can advantageously be identified early.

It is also proposed that the method includes at least one standardization step, in which the contents of different learning documents or different construction documents are mapped to uniform processing parameters by applying abstraction rules, which are further processed for learning the meaning or evaluating the construction project. For example, one of the abstraction rules maps at least one of the content objects of the content of the construction document or of the learning document and optionally the recorded properties of the content object to one of the processing parameters. In particular, at least one of the abstraction rules combines a number of content objects and optionally the properties of these content objects with a further one of the processing parameters. The abstraction rules particularly preferably map all content objects of the content of the learning document or the construction document to the processing parameters. In particular, the processor unit uses the processing parameters, in particular instead of the original content objects, as input data for machine learning and/or scoring. For example, the abstraction rules include the content objects "Text Box 1", "Arrow" and "Text Box 2" and their properties "relative position" and "Off direction" to the processing parameter "Text box 1 points to text box 2". The abstraction rules are stored in the memory unit in particular in advance of the method. In particular, at least two abstraction rules map the same type of processing parameters to two different content objects. Preferably, the abstraction rules standardize the content objects. In particular, the abstraction rules reduce a number of different types of content objects across all document types to a predetermined number of different types of processing parameters. In particular, the processor unit assigns the same type of processing parameters to different document types using the abstraction rules. In particular, the abstraction rules encode the content of the construction document and/or the learning document, in particular by converting the content objects formatted by the source of the construction document and/or the learning document into the uniform evaluation parameters. The artificial neural network, which uses the evaluation parameters as input data, can advantageously be quickly trained with advantageously few training documents as a result of the configuration according to the invention. In particular, by updating the abstraction rules, new types of file formats for construction documents can advantageously be integrated into the method quickly and easily, in particular without having to relearn the artificial neural network.

It is further proposed that the method includes an individual document step in which the meaning of the content of the training document or the construction document is learned independently of a meaning of the content of a further training document or is evaluated independently of a meaning of the content of a further construction document. In particular, the processor unit processes each learning document and/or each construction document separately in the individual document step. In particular, the method includes a construction project step that follows the individual document step, in which the meaning of a plurality of learning documents and/or construction documents are linked to one another in order to determine the target parameter. In particular, the single document step is performed by means of the artificial neural network. The construction project step is carried out in particular by means of the artificial neural network and/or by means of the further artificial neural network. In particular, the artificial neural network in the individual document converts the content objects of an individual learning document and/or an individual construction document into corresponding meaning elements. The meaning elements which are assigned to an individual construction document and/or learning document by the artificial neural network are preferably stored in the memory unit. Due to the configuration according to the invention, the meaning, the meaning elements, of a construction document and/or learning document can be reused for an advantageously large number of different analyses. In particular, if the construction document and/or the learning document is misinterpreted or if a construction document that does not belong to the construction project is input, error correction can advantageously be carried out easily.

Furthermore, it is proposed that in at least one method step of the method the content of the learning document and/or the construction document is assigned a time stamp, which is evaluated to evaluate the construction project. The at least one learning document and/or the at least one construction document can have a creation date, a service period or the like as part of the original content as time information or can be subsequently provided with a physical or digital entry stamp. In particular, the processor unit records the time information as a content object and recognizes its meaning using the artificial neural network. In particular, the processor unit assigns a time stamp to the at least one training document and/or the at least one construction document, which time stamp corresponds to the time specification within the training document or the construction document. If the construction document or the training document has no time information or if a time information of the construction document or the training document is not recognized by the artificial neural network, the processor unit preferably assigns a standard time stamp to the construction document or the training document as a time stamp. The standard time stamp is, for example, a creation time of a file in which the construction document or the learning document is stored. The data processing device preferably informs a user that a standard time stamp has been assigned and/or asks a user for a specific time stamp that is to be assigned to the construction document or the learning document instead of the standard time stamp. Due to the configuration according to the invention, the construction project can advantageously be evaluated in a time-resolved manner. In particular, the target parameter can advantageously be evaluated at any point in time.

Furthermore, it is proposed that in at least one method step of the method a point in time is queried from an external source, with the evaluation of the construction project evaluating a predicted state of the construction project in which the construction project is at the queried point in time. Preferably, the predicted state is preceded by an additional artificial neural network of the data processing direction created. In particular, the processor unit transfers the meaning elements that the artificial neural network has determined, together with the queried point in time, to an input layer of the additional neural network. In particular, the additional neural network outputs a predicted value of the target parameter, which the target parameter assumes at the queried point in time, to an output layer of the additional neural network. The external source can in particular be a user of the method and/or an external program, for example for an automated graphic processing of the analysis or the like. The configuration according to the invention makes it possible to advantageously identify problems at an early stage. In particular, a warning can advantageously be issued at an early stage. In particular, a need for action can advantageously be pointed out at an early stage.

In addition, it is proposed that the contents of learning documents for different construction projects be evaluated in at least one method step of the method in order to create the analysis of the construction project. In particular, a further construction project is evaluated in at least one method step in order to create the analysis of the construction project. Depending in particular on the target parameter of the analysis to be output, the further construction project can be completed, under construction or in a planning phase. Examples of target parameters, which can be obtained in particular from an evaluation of several construction projects, include an overall financial situation, in particular liquidity, of a general contractor, reliability of a subcontractor, availability or delivery bottlenecks of raw materials and/or prefabricated parts or the like. The configuration according to the invention advantageously makes it possible to obtain a great deal of information that is relevant to the construction project. In particular, information can be obtained which, viewed alone, cannot be directly derived from the construction documents for the construction project.

It is also proposed that at least one of the method steps of the method be carried out by an artificial neural network, in particular by at least one of the artificial neural networks already mentioned, and at least one further of the method steps of the method by another artificial neural network, in particular by at least one of the already mentioned artificial neural networks, which is designed at least partially, in particular completely, independently of the artificial neural network. In particular, the single document step is performed by the artificial neural network. The assessment of a state of the construction project at a point in time when the method is being carried out is preferably carried out by the further artificial neural network. The creation of a prognosis about a state of the construction project is preferably carried out by the additional artificial neural network after a point in time of the method. Optionally, the capturing of the content objects is performed by a content capturing artificial neural network. At least the additional artificial neural network and the additional artificial neural network are preferably configured separately from one another. The artificial neural network and the artificial neural content acquisition network can be designed separately from one another or integrated into one another. The artificial neural network and the further artificial neural network can be designed separately from one another or integrated into one another. The artificial neural network and the additional artificial neural network can be designed separately from one another or integrated into one another. Two artificial neural networks are integrated into one another, in particular, if the output layer of one artificial neural network is the same as the input layer of the other artificial neural network and this input layer and this output layer form an intermediate layer of the artificial neural networks integrated into one another. In particular, the artificial neural networks that are integrated into one another are trained by common machine learning, in which in particular data streams at the intermediate layer formed by the input layer of one artificial neural network and the output layer of the other neural network are not explicitly monitored. The artificial neural networks of two artificial neural networks that are integrated into one another can each have a different architecture or have the same architecture. Optionally, the further artificial neural network and the additional artificial neural network have a common input layer and separate output layers.

Two separately designed artificial neural networks each have, in particular, an output layer and an input layer that is independent of the output layer and the input layer of the other artificial neural network in each case. In particular, data at the output layers of separately formed artificial neural networks are present in an explicit form and can be stored in the memory unit. In particular, separately designed artificial neural networks are trained independently of one another, with preferably data streams at each of the output layers of the separately designed be monitored by artificial neural networks. The configuration according to the invention allows a modular sequence of the method to be achieved. In particular, the method can advantageously be modified simply by replacing only one of the artificial neural networks. In particular, intermediate results of the method, for example the recorded content objects and/or the determined meaning elements, can advantageously be documented. In particular, artificial neural networks with a more specific task can be trained with advantageously few training documents. In particular, each individual artificial neural network can advantageously be kept small.

In addition, it is proposed that at least one stateless artificial neural network is used to evaluate the construction project. In particular, the artificial neural network is designed to be stateless, for example as a convolutional neural network (CNN), in particular as a one-dimensional CNN. Preferably, the artificial neural network processes a training document or a construction document as a whole. In particular, the processor unit transfers an entire unit of the content objects of the at least one construction document or the at least one learning document to an input layer of the artificial neural network. In particular, the artificial neural network outputs a representation of the construction document or the training document which is composed of elements of meaning which the artificial neural network has recognized in the content objects of this construction document or this training document. In particular, the artificial neural network constructs the representation of the build document using a feed-forward traversal. Alternatively, the artificial neural network is designed to be state-dependent. Alternatively, the artificial neural network has a transformer architecture. Alternatively, the artificial neural network is designed as a combination of a CNN with a recurrent neural network (RNN).

For example, the artificial neural content detection network is designed as a stateless artificial neural network, for example as a CNN, in particular as a two-dimensional CNN. The artificial neural content acquisition network preferably acquires, in particular graphic and/or textual, content objects of the at least one learning document or of the at least one construction document, which are present in an image format. Alternatively, the content objects of the at least one learning document or the at least one construction document are recorded using optical character recognition (OCR). As a result of the configuration according to the invention, an output from the artificial neural network is exclusively dependent on the current input data and in particular not on a previous acquisition or evaluation of other documents. In particular, a continuation of an error in the detection or evaluation of a document on another document can be advantageously avoided.

Furthermore, it is proposed that at least one stateful artificial neural network be used to evaluate the construction project. For example, the artificial neural network is embodied as a stateful artificial neural network, in particular as an RNN. An RNN for the method, in particular the artificial neural network, can be implemented, for example, as a long short-term memory (LSTM) or as a gated recurrent unit (GRU). An RNN for the method, in particular the artificial neural network, is optionally implemented as a bi-directional RNN. In particular, the processor unit transfers the at least one construction document or the at least one training document to the artificial neural network as a sequence of content objects of the construction document or of the training document. The sequence of content objects preferably includes a variable number of content objects at each time step, for example exactly one content object, in particular so that the artificial neural network generates exactly one meaning element at the output layer of the artificial neural network.

The further artificial neural network and/or the additional neural network is/are preferably in the form of a state, in particular in the form of an RNN. Preferably, a head, in particular the output layer and at least one further layer, of the further artificial neural network and/or a head, in particular the output layer and at least one further layer, of the additional neural network is fully meshed. In particular, the processor unit feeds a total of available construction documents or learning documents as a sequence of individual documents to the input layer of the further artificial neural network and/or the additional neural network. Alternatively, the further artificial neural network and/or the additional neural network is designed as a stateless artificial neural network, in particular as a one-dimensional CNN, or has a transformer architecture. Due to the configuration according to the invention, the documents can advantageously be processed at different times. In particular, a quasi-simultaneous transfer of all documents to the further artificial neural network or the additional artificial neural network can be dispensed with. In particular, the method be carried out with a data processing device with an advantageously small (working) memory capacity and/or an advantageously low processor performance.

Furthermore, a data processing device is proposed which comprises a processor which is configured in such a way that it executes the method steps of the method according to the invention. The processor is in particular part of the processor unit. The processor unit has, in particular, a Von Neumann architecture and/or Harvard architecture, a vector processor, a number of parallel processors or neuromorphic electronics in order to carry out the method steps of the method. The data processing unit includes in particular the memory unit. The data processing unit includes in particular the input unit. The input unit includes, for example, a keyboard, a mouse, a touch screen, a card reader and/or a data interface for an external digitizing device, for example a scanner, a fax machine, a digital camera or the like. The input unit is intended in particular to provide the at least one learning document, the at least one construction document and/or supplementary information. The data processing unit preferably comprises at least one output unit for outputting the analysis, in particular the at least one target parameter, and/or for outputting a (warning) information derived from the analysis. The output unit includes, for example, a display, a loudspeaker and/or an interface for an external output device, for example a mobile phone, a tablet, a printer or the like. The configuration according to the invention makes it possible to provide a data processing device with the aid of which construction projects can be planned and carried out efficiently, cost-effectively and with few errors.

In addition, a computer program is proposed which includes instructions which, when the program is executed by a computer, cause the latter to carry out the steps of the method. In particular, the computer program causes the computer to capture the content objects of the at least one construction document and/or the at least one learning document. Preferably, the computer program causes the computer to map the content objects to the meaning elements. In particular, the computer program prompts the computer to determine the target parameter of the analysis as a function of the elements of meaning, in particular a number of construction documents. The computer program preferably prompts the computer to output the target parameter, in particular as a function of a point in time requested by an operator of the computer. The configuration according to the invention makes it possible to provide a computer program with the aid of which construction projects can be planned and carried out efficiently, cost-effectively and with few errors.

The method according to the invention, the device for data processing according to the invention and/or the computer program according to the invention should/should not be limited to the application and embodiment described above. In particular, the method according to the invention, the device for data processing according to the invention and/or the computer program according to the invention can have a number of individual elements, components and units as well as method steps that differs from the number specified herein to fulfill a function described herein. In addition, in the value ranges specified in this disclosure, values lying within the specified limits should also be considered disclosed and can be used as desired.

character list

Further advantages result from the following description of the drawing. Three exemplary embodiments of the invention are shown in the drawings. The drawings, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into further meaningful combinations.

• 1 eine schematische Darstellung einer erfindungsgemäßen Datenverarbeitungsvorrichtung,
• 2 ein schematisches Flussdiagramm eines erfindungsgemäßen Verfahrens,
• 3 ein schematisches Flussdiagramm zur Bereitstellung eines Inhalts eines Baudokuments und/oder eines Lerndokuments im Zuge des erfindungsgemäßen Verfahrens,
• 4 ein schematisches Flussdiagramm zur Erstellung von Bedeutungselementen aus dem Inhalt des Baudokuments und/oder des Lerndokuments im Zuge des erfindungsgemäßen Verfahrens,
• 5 ein schematisches Flussdiagramm zum maschinellen Lernen einer Bedeutung des Inhalts des Baudokuments und/oder des Lerndokuments im Zuge des erfindungsgemäßen Verfahrens,
• 6 ein schematisches Flussdiagramm zur Ermittlung eines Zielparameters in Abhängigkeit von den Bedeutungselementen im Zuge des erfindungsgemäßen Verfahrens,
• 7 ein schematisches Flussdiagramm zum maschinellen Lernen einer Abhängigkeit des Zielparameters von den Bedeutungselementen im Zuge des erfindungsgemäßen Verfahrens,
• 8 ein schematisches Flussdiagramm eines Analyseschritts des erfindungsgemäßen Verfahrens.
• 9 ein schematisches Flussdiagramm eines Datenflusses zu einer Prognose des Zielparameters zu einem vorgegebenen Zeitpunkt,
• 10 ein schematisches Flussdiagramm eines alternativen erfindungsgemäßen Verfahrens und
• 11 ein schematisches Flussdiagramm eines weiteren alternativen Verfahrens.

Show it:

• 1 a schematic representation of a data processing device according to the invention,
• 2 a schematic flow chart of a method according to the invention,
• 3 a schematic flowchart for providing content of a construction document and/or a learning document in the course of the method according to the invention,
• 4 a schematic flow chart for creating meaning elements from the content of the construction document and/or the learning document in the course of the method according to the invention,
• 5 a schematic flow chart for machine learning of a meaning of the content of the construction document and/or the learning document in the course of the method according to the invention,
• 6 a schematic flowchart for determining a target parameter as a function of the elements of meaning in the course of the method according to the invention,
• 7 a schematic flowchart for machine learning of a dependency of the target parameter on the meaning elements in the course of the method according to the invention,
• 8th a schematic flow chart of an analysis step of the method according to the invention.
• 9 a schematic flowchart of a data flow for a forecast of the target parameter at a specified point in time,
• 10 a schematic flow diagram of an alternative method according to the invention and
• 11 a schematic flow diagram of a further alternative method.

Description of the exemplary embodiments

1 shows a data processing device 46a, for example a computer. The data processing device 46a includes a processor unit 48a with at least one processor. The processor is configured to perform steps of a method 10a that are described in FIGS 2 until 11 is described in more detail. Method 10a is intended to support planning and organization of a construction project by extracting information from at least one construction document 12a, 14a relating to the construction project (cf. 2 ) intended. The data processing device 46a preferably comprises a memory unit 50a. In particular, a computer program is stored in the memory unit 50a. The computer program includes instructions which, when the computer program is executed by the data processing device 46a, cause the latter to carry out the steps of the method 10a. The data processing device 46a comprises in particular an input unit 54a for storing the construction documents 12a, 14a in the storage unit 50a and/or for manually entering data in the course of the method 10a. The data processing device 46a includes, in particular, an output unit 52a for outputting an analysis 24a, 26a of the construction project (cf. 2 ). The data processing device 46a preferably comprises at least one artificial neural network 40a. The data processing device 46a preferably comprises at least one further artificial neural network 42a. The data processing device 46a preferably comprises at least one additional artificial neural network 44a. The data processing device 46a optionally comprises an artificial neural content acquisition network 38a. The artificial neural networks 38a, 40a, 42a, 44a are provided in the course of the method 10a, in particular for creating the analysis 24a, 26a of the construction project as a function of the construction documents 12a, 14a.

2 shows a flow chart of the method 10a. The method 10a includes in particular a learning phase and an execution phase. In the learning phase, the artificial neural networks 38a, 40a, 42a, 44a are preferably trained using learning documents 18a, 20a. In the execution phase, the construction documents 12a, 14a are preferably analyzed by the trained artificial neural networks 40a, 42a, 44a. In the execution phase, the method 10a includes in particular a pre-processing step 56a. In the pre-processing step 56a, content of the construction document 12a, 14a is provided, in particular recorded. The pre-processing step 56a is performed, for example, by the artificial neural content detection network 38a or by pattern recognition software. In the pre-processing step 56a, the artificial neural content detection network 38a or the pattern recognition software detects in particular content objects 62a from which a content of the construction documents 12a, 14a is composed.

In the execution phase, the method 10a includes a single document step 32a. In the individual document step 32a, a meaning of the content of the building document 12a is evaluated independently of a meaning of the content of the further building document 14a. Specifically, the single document step 32a is performed by the artificial neural network 40a. In the single document step 32a, the artificial neural network 40a processes in particular the content objects 62a detected in the pre-processing step 56a. In particular, the artificial neural network 40a creates at least one meaning element 64a of the construction document 12a or of the further construction document 14a depending on the recorded content objects 62a of the corresponding construction document 12a, 14a.

In the execution phase, the method 10a includes in particular an analysis step 58a. In the analysis step 58a, the construction project is evaluated by applying the learned meaning to the content of the construction document 12a, 14a. In the analysis step 58a, the analysis 24a of the construction project created in the course of the evaluation is output. The analysis step 58a is carried out in particular by the further artificial neural network 42a. In the analysis step 58a, the further artificial neural network 42a evaluates in particular the meaning element 64a created in the individual document step 32a, in particular the meaning elements 64a created for a multiplicity of construction documents 12a, 14a. In particular, the further artificial neural network 42a determines at least a value of a target parameter of the analysis 24a of the construction project as a function of the significance element 64a created. The target parameter indicates, for example, construction progress of the construction project, in particular a deviation from a schedule. The target parameter indicates, for example, construction costs of the construction project, in particular a deviation from costs estimated in advance. The target parameter indicates, for example, an incorrect planning, for example a collision of schedules. The target parameter indicates, for example, a risk, for example a probability of default of a subcontractor.

In the execution phase, the method 10a includes, in particular, a prognosis step 60a. In the prediction step 60a, the construction project is evaluated by applying the learned meaning to the content of the construction document 12a, 14a. In the prognosis step 60a, a further analysis 26a of the construction project, created in the course of the evaluation, is output. The prediction step 60a is preferably performed by the additional artificial neural network 44a. In the prognosis step 60a, the additional artificial neural network 44a evaluates in particular the meaning element 64a created in the individual document step 32a, in particular the meaning elements 64a created for a multiplicity of construction documents 12a, 14a. In particular, the additional artificial neural network 44a predicts at least one value of a target parameter of the further analysis 26a of the construction project as a function of the significance element 64a created. For example, the additional artificial neural network 44a predicts a material requirement and/or a remaining stock at a specified point in time 36a (cf. 9 ), costs incurred and/or remaining funds at the specified point in time 36a, construction progress at the specified point in time 36a or the like.

In the learning phase, the data processing device 46a preferably processes the learning documents 18a, 20a. The learning documents 18a, 20a document a completed old project. Depending on which of the artificial neural networks 38a, 40a, 42a, 44a is trained, the learning phase includes the preprocessing step 56a, the individual document step 32a, the analysis step 58a and/or the prognosis step 60a. In the pre-processing step 56a, content of the learning documents 18a, 20a is provided, in particular recorded. Optionally, in the pre-processing step 56a, the acquisition of content objects 62a by the artificial neural content acquisition network 38a is learned during the learning phase. In the individual document step 32a, the analysis step 58a and/or the prognosis step 60a, the meaning of the content of the learning documents 18a, 20a is learned from the artificial neural networks 40a, 42a, 44a by means of machine learning 22a.

3 Figure 5 shows a flow chart of the pre-processing step 56a. The pre-processing step 56a is preferably carried out individually for each document to be processed. If the processor unit 48a includes a number of processors, a number of pre-processing steps 56a can be carried out in parallel. The document to be processed can be the construction document 12a, 14a or the training document 18a, 20a. In the pre-processing step 56a, the documents to be processed are preferably stored in the storage unit 50a. The documents to be processed can be stored by a user, in particular by copying them from an external storage medium, and/or can be carried out automatically by the processor unit 48a, for example by retrieving them from databases, e-mail programs, data networks or the like. Physically present documents, for example the further construction document 14a or the further learning document 20a, are preferably digitized in the pre-processing step 56a, in particular by means of a scanner, a digital camera or the like. The pre-processing step 56a is provided in particular for detecting the content of the documents to be processed. In the pre-processing step 56a, the data processing device 46a particularly preferably creates a representation of the document to be processed, which consists of content objects 62a. The content object 62a of the document to be processed is, for example, a text element 66a and/or a graphic element 68a, such as a photo, a line, a circle, an arrow or the like. If the document to be processed, for example the construction document 12a or the training document 18a, is already available in a file format which organizes the content of the document into objects, the processor unit 48a preferably reads these objects as content objects 62a. For example, word processors, vector graphics programs, spreadsheet programs, architecture programs, or the like organize the content of the documents they create into objects. If the document to be processed, for example the additional construction document 14a or the additional learning document 20a, is in an image file format, the processor unit 48a captures the content of the document to be processed, preferably by means of at least one pattern recognition routine 70a. The pattern recognition routine 70a may be implemented by the content detection artificial neural network 38a or by any other method known in the art. In particular, in an advantageously simple embodiment of the method 10a, text elements 66a of the document to be processed are recognized by means of Optical Character Recogni tion 72a recorded. At least one property 74a of the content object 62a is particularly preferably recorded in addition to the content object 62a. Examples of the property 74a of the content object 62a include a position within the document to be processed, a size, a color, an orientation, a font, a relationship to another content object, such as specifically "is within", "points to", or the like.

The method includes a unification step 28a. In the unification step 28a, contents of different learning documents 18a, 20a or different construction documents 12a, 14a are mapped to uniform processing parameters 30a by applying abstraction rules. The uniform processing parameters 30a are further processed for learning the meaning or evaluating the construction project, in particular in place of the content objects 62a in an originally recorded file format. In particular, the abstraction rules map the content objects 62a, in particular the text elements 66a, the graphic elements 68a and/or the properties 74a, to the uniform processing parameters 30a, in particular to uniform text elements 66a', uniform graphic elements 68a' and/or uniform properties 74a'. Preferably, at least one abstraction rule maps multiple content objects 62a of a document to be processed to a single, uniform processing parameter 30a. In particular, in the pre-processing step 56a, the data processing device 46a normalizes the documents to be processed, which are present in particular in different file formats, to a format which is defined by the uniform processing parameters 30a.

4 Figure 3 shows a flow chart of the single document step 32a in the execution phase. In the individual document step 32a, the artificial neural network 40a processes the content objects 62a, in particular the uniform processing parameters 30a, of an individual document to be processed in order to assign at least one meaning element 64a to this document. In particular, in the single document step 32a, a representation of the document to be processed is created, which is composed of one or more meaning elements 64a. Meaning elements 64a include, for example, a creation date of the document to be processed, a document type of the document to be processed, for example an invoice, a floor plan, an inventory list or the like, an author of the document to be processed, an invoice amount, a delivery quantity, an inventory quantity or the like. A stateless artificial neural network is used to determine the meaning element 64a. In particular, the artificial neural network 40a is designed as a stateless artificial neural network. The artificial neural network 40a is particularly preferably designed as a deep artificial neural network. The single document step 32a preferably includes encoding 76a. In the coding 76a, the content objects 62a, in particular the uniform processing parameters 30a, of one, in particular individual, documents to be processed are converted to a form that is compatible with an input layer of the artificial neural network 40a. In particular, the processor unit 48a creates a list of the, in particular all, recorded content objects 62a, in particular the uniform processing parameters 30a, of one of the documents to be processed. The properties 74a, in particular the standardized properties 74a′, are preferably encoded by a number vector, with each vector element of the number vector representing in particular one of the properties 74a, in particular the standardized properties 74a′. Properties 74a, 74a', which represent a numerical value, are preferably normalized. Properties 74a, 74a' of the enumeration type, such as for defining the type of graphic element 68a, 68a', are assigned, for example, a numerical value specified during the learning phase. The text elements 66a, 66a' are preferably coded word for word into a vector by means of a dictionary. Optionally, each word within a document to be processed is listed as its own content object 62a, in particular as its own uniform processing parameter 30a, on the list of content objects 62a. The graphic elements 68a, 68a' are preferably encoded as a vector. The list of content objects 62a, in particular the uniform processing parameters 30a, is encoded in the encoding 76a in particular in a matrix, which is transferred from the processor unit 48a to an input layer of the artificial neural network 40a. The individual document step 32a includes in particular a meaning recognition 80a, in which the content objects 62a, in particular the uniform processing parameters 30a, are processed by the artificial neural network 40a. In particular, the single document step 32a includes a decoding 78a, in which the processor unit 48a assigns at least one meaning element 64a to an output of the artificial neural network 40a.

5 shows a flowchart for generating a learning data record 33a for machine learning 22a of the individual document step 32a. In particular, in the learning phase, the content objects 62a of the learning documents 18a, 20a are recorded by the pre-processing step 56a and are preferably mapped to the standardized processing parameters 30a. The learning documents 18a, 20a are preferably edited by a user of the method 10a. A preparation 82a of the learning documents 18a, 20a includes in particular adding or marking the meaning element 64a to be learned on the learning documents 18a, 20a in physical or digital form, in particular before, during or after the pre-processing step 56a. The meaning element 64a to be learned is encoded by the processor unit 48a, in particular analogously to the content objects 62a, and is used during the machine learning 22a as a target value for the output of the artificial neural network 40a.

6 shows a flow chart for creating the analysis 24a by means of the analysis step 58a. A plurality of construction documents 12a, 14a are preferably provided and processed in particular in each case in the pre-processing step 56a and the individual document step 32a to form a representation of the corresponding construction document 12a, 14a by meaning elements 64a. In particular, the processor unit 48a supplies the meaning elements 64a to an input layer of the further artificial neural network 42a. The further artificial neural network 42a outputs in particular the target parameter of the analysis 24a. In at least one method step, the content of the construction documents 12a, 14a is assigned a time stamp 34a, which is evaluated to evaluate the construction project. The timestamp 34a is preferably processed as one of the meaning elements 64a. In the analysis step 58a, the contents of learning documents 18a, 20a for different construction projects can be evaluated in order to create the analysis 24a of the construction project.

7 shows a flowchart for learning the target parameter of the analysis 24a. A plurality of learning documents 18a, 20a are preferably provided and in particular processed in each case in the pre-processing step 56a and the individual document step 32a to form a representation of the corresponding learning document 18a, 20a by meaning elements 64a. In at least one method step, a time stamp 34a is assigned to the content of the learning documents 18a, 20a. Learning documents 18a, 20a are preferably provided and processed by different old projects, with the documents being processed in particular grouped by old project. The learning documents 18a, 20a are prepared in particular in a target parameter specification 84a by a user of the method 10a. The target parameter specification 84a of the learning documents 18a, 20a includes in particular adding or marking the target parameter to be learned on the learning documents 18a, 20a in physical or digital form, in particular before, during or after the pre-processing step 56a and/or the individual document step 32a. The target parameter of the analysis 24a to be learned is encoded by the processor unit 48a, in particular analogously to the content objects 62a, and used during the machine learning 22a as a target value for the output of the further artificial neural network 42a. In particular, in the case of machine learning 22a, a chronological sequence of the target parameter, in particular for each old project, is learned using the time stamp 34a of different learning documents 18a, 20a.

8th shows a flow chart of the analysis step 58a. The further artificial neural network 42a preferably evaluates the meaning elements 64a of the construction documents 12a, 14a as a sequence. The further artificial neural network 42a optionally evaluates the semantic elements 64a′ of the construction documents 12a, 14a as a further sequence, which in particular has an inverse order of the semantic elements 64a and/or the construction documents 12a, 14a relative to the sequence. The further artificial neural network 42a is in the form of a state-based artificial neural network. The analysis step 58a includes, in particular, a meaning coding 86a, in which the meaning elements 64a of the construction documents 12a, 14a are coded by the processor unit 48a in a manner analogous to the content objects 62a during the coding 76a and are transferred to an input layer of the further artificial neural network 42a. In particular, the analysis step 58a includes a project meaning recognition 88a, in which the further artificial neural network 42a maps the meaning elements 64a to the target parameter of the analysis 24a.

9 shows a flow chart for creating the further analysis 26a by means of the prognosis step 60a. A plurality of construction documents 12a, 14a are preferably provided and processed in particular in each case in the pre-processing step 56a and the individual document step 32a to form a representation of the corresponding construction document 12a, 14a by meaning elements 64a. In at least one method step, the point in time 36a is queried from an external source, for example a user. When evaluating the construction project, a predicted state of the construction project is evaluated, in which the construction project is at the queried point in time 36a. In particular, the processor unit 48a supplies the meaning elements 64a plus the point in time 36a to an input layer of the additional artificial neural network 44a. The additional artificial neural network 44a outputs, in particular, a value of the target parameter of the analysis 24a, as it is expected to result at the queried point in time 36a. The additional artificial neural Network 44a is preferably designed as a stateful artificial neural network. The additional artificial neural network 44a is formed at least partially, in particular completely, independently of the further artificial neural network 42a.

In the 10 and 11 two further exemplary embodiments of the invention are shown. The following descriptions and the drawings are essentially limited to the differences between the exemplary embodiments, with regard to components having the same designation, in particular with regard to components having the same reference symbols, also to the drawings and/or the description of the other exemplary embodiments, in particular the 1 until 9 , can be referenced. To distinguish between the exemplary embodiments, the letter a is the reference number of the exemplary embodiment in FIGS 1 until 9 adjusted. In the embodiments of 10 until 11 the letter a is replaced by the letters b to c.

10 10 shows a computer-implemented method 10b for supporting planning and organization of a construction project by extracting information from at least one construction document relating to the construction project. The method 10b comprises the method steps: providing, in particular detecting, the content of at least one learning document which documents at least one completed old project; learning a meaning of the content of the learning document using machine learning; Providing, in particular recording, content of the construction document; Evaluate the construction project by applying the learned meaning to the content of the construction document and outputting an analysis 24b of the construction project generated during the evaluation. In particular, the method 10b includes a meaning detector 80b and a project meaning detector 88b performed by a single artificial neural network. The artificial neural network is designed in particular as a recurrent neural network. In particular, in a learning phase of the method 10b, a direct connection between content objects 62b of the learning documents and a target parameter of the analysis 24b is learned, in particular without explicit learning of meaning elements of the individual learning documents. In an execution phase of the method 10b, the artificial neural network preferably evaluates the content objects 62b of the construction documents as a sequence. The artificial neural network optionally evaluates the content objects 62b′ of the construction documents as a further sequence, which in particular has an inverse order of the content objects 62b and/or the construction documents relative to the sequence. In particular, the method 10b with the artificial neural network combines a single document step and an analysis step of the method 10b.

Regarding other features of the method 10b is on the 1 until 9 and their description referenced.

11 10 shows a computer-implemented method 10c for supporting planning and organization of a construction project by extracting information from at least one construction document relating to the construction project. The method 10c comprises the method steps: providing, in particular detecting, the content of at least one learning document which documents at least one completed old project; learning a meaning of the content of the learning document using machine learning; Providing, in particular recording, content of the construction document; Assess the construction project by applying the learned meaning to the content of the construction document and outputting an analysis of the construction project generated during the assessment.

The method 10c includes, in particular, at least two method steps, which are carried out by a multi-stage artificial neural network. In particular, the artificial neural network comprises a first stage and a second stage, with an input layer of the second stage being identical to an output layer of the first stage. The first stage is designed, for example, as a convolutional neural network. The second stage is designed as a recurrent neural network, for example. The first stage is provided in particular for carrying out a meaning recognition 80c of the method 10c. The second stage is provided in particular for carrying out a project significance recognition 88c of the method 10c, in particular for creating an analysis or a prognosis. In particular, in a learning phase of the method 10c, a direct connection between content objects 62c of the learning documents and a target parameter of the analysis or the prognosis is learned, in particular without explicit learning of meaning elements of the individual learning documents. Optionally, the second stage includes a fully meshed output layer 90c. In particular, the method 10c with the multi-stage artificial neural network combines a single document step and an analysis step or the single document step with a prognosis step of the method 10c.

Regarding other features of the method 10c is on the 1 until 10 as well as their description.

Claims (11)

Computer-implemented method for supporting planning and organization of a construction project by extracting information from at least one construction document (12a, 14a) relating to the construction project, comprising the method steps: • Providing, in particular recording, the content of at least one learning document (18a, 20a) which documents at least one completed old project, • learning a meaning of the content of the learning document (18a, 20a) using machine learning (22a), • Providing, in particular recording, a content of the construction document (12a, 14a), • Assess the construction project by applying the learned meaning to the content of the construction document (12a, 14a) and • Output of an analysis (24a, 26a) of the construction project created in the course of the evaluation. Computer-implemented method claim 1 , Characterized by at least one standardization step (28a), in which the contents of different learning documents (18a, 20a) or different construction documents (12a, 14a) are each combined by applying abstraction rules, which in particular several objects that make up the respective content, a single new Assigns object to uniform processing parameters (30a) are mapped, which are further processed for learning the meaning or evaluating the construction project. Computer-implemented method claim 1 or 2 , characterized by a single document step (32a), in which the meaning of the content of the learning document (18a) or the construction document (12a) is learned independently of a meaning of the content of a further learning document (20a) or a further construction document (14a) is evaluated. Computer-implemented method according to one of the preceding claims, characterized in that in at least one method step the content of the learning document (18a, 20a) and/or the construction document (12a, 14a) is assigned a time stamp (34a) which is evaluated to evaluate the construction project becomes. Computer-implemented method according to one of the preceding claims, characterized in that in at least one method step a point in time (36a) is queried from an external source, with the evaluation of the construction project evaluating a forecast state of the construction project in which the construction project is at the queried Time (36a) is located. Computer-implemented method according to one of the preceding claims, characterized in that the contents of learning documents (18a, 20a) for different construction projects are evaluated in at least one method step in order to create the analysis (24a, 26a) of the construction project. Computer-implemented method according to one of the preceding claims, characterized in that at least one of the method steps is carried out by an artificial neural network (40a) and at least one further of the method steps is carried out by a further artificial neural network (38a, 42a, 44a) which is at least is formed partially, in particular completely, independently of the artificial neural network (40a). Computer-implemented method according to one of the preceding claims, characterized in that at least one stateless artificial neural network is used to evaluate the construction project. Computer-implemented method according to one of the preceding claims, characterized in that at least one stateful artificial neural network is used to evaluate the construction project. A data processing device comprising a processor configured to perform the steps of the method of any one of Claims 1 until 9 executes Computer program, comprising instructions which, when the computer program is executed by a computer, cause the latter to carry out the steps of the method according to one of Claims 1 until 9 to execute.

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