NL8820470A - NOTIFICATION SYSTEM. - Google Patents

Description

Title: Notification system.

The invention relates to a knowledge system, more particularly intended for managing and controlling a number of complex tasks using parallel processing. In addition, the architecture of the system is of a form, whereby high-level artificial intelligence can be realized for managing and controlling the parallel processing of a number of and simultaneous events.

There are widely divergent judgments about what constitutes true artificial intelligence.

The current emphasis is clearly on new programming "software" devices intended to communicate some degree of artificial intelligence to conventional computing devices.

It is the duty of one skilled in the art of artificial intelligence system "hardware" to provide more effective methods for taking into account the rapid growth of program areas and their complexity. This requirement is met by so-called parallel processing, which is ideally accompanied by increased disk operating speeds, such as "header placement times," etc. Lookup methods, relational databases, content addressing capabilities are among the other methods that arise in the pursuit of improved overall computing performance.

Artificial intelligence systems can be broadly split into the two areas of deductive or inductive reasoning with a predominant obligation that such systems possess the means of learning.

Although the literature has for some time included discussions of cognitive modeling or brain modeling, the use of the emerging methods has been scarce and continues to be applied to conventional or orthodox serial and sequential disk calculators on von Neumann -base. Examples are found in parallel processing, where the demand for more effective communication is obtained through Boolean N Cube Models. In these models, Neuron nets, which mimic a child's brain cell activity, are deployed within traditional "software" programming. Therefore, attention is being paid to improving memory utilization through disk sharing and "virtual" memory systems, in which the demand for ever faster data paths and processing through high speed integrated chains (VHISIC) and more effective media are met , such as gallium arsenide and gallium aluminum arsenide. With such media, memory access speeds in the tens of nanosec range are obtained, but computing systems, using parallel processing methods using such media for processing information, are still surpassed by the human brain, a system with maximum conduction rates of 300 milliseconds. .

Despite these limitations, the designers have shown their reluctance to move away from traditional design concepts, and therefore paradigms have been developed, which include restrictive processing methods, such as: - developing "software" to be used in business calculators, - adding coprocessors to serial calculators, developing VLSI chains containing large numbers of processor elements in neural networks.

Some systems are able to achieve low-level intelligence status through the incorporation of stored logical adaptive microchains, neural networks, multilayer constructions, feedback mechanisms and short-term memories, but so far the forerunners of artificial intelligence have not been developed machines, which can learn themselves. It appears that an important factor contributing to this inability lies in the fact that the designers still use basic structures embedded in Von Neumann architecture and to obtain a high level of artificial intelligence in a computing device it is necessary to look for other architectures, which provide a more conducive environment to provide perception in a machine structure.

Therefore, it is an object of the invention to provide a notification system, which provides an appropriate environment to control a number of complex tasks using parallel processing in an efficient, reliable and relatively inexpensive manner.

According to one aspect of the invention, there is provided an acquaintance system for managing and controlling a number of complex tasks using parallel processing comprising: a number of discrete intelligent processors, each capable of performing specific tasks; memory means intended for receiving and presenting information for examination by such an intelligent processor for determining the storage of this information, the memory means being provided with a series of memory elements, which are present at prescribed locations for the storage of this information information; means to allow one intelligent processor to cooperate with another by enabling direct communications between them; and interfaces for input and output information to or from the system, the intelligent processors comprising management means intended to organize and direct the information to the memory devices received from the interface devices to the memory devices, taking into account an understanding of the system, and organizing and directing communications between the processors and the interfaces.

The discrete intelligent processors work together and are also able to perform tasks in addition to the specific tasks.

Preferably, the information is stored relationally in the prescribed locations of the memory members.

Preferably, the memory members are split into discrete memory parts related to the tasks of the intelligent processors, whereby information relevant to one task or another task is stored in an appropriate memory part in order to provide the relational arrangement of information, stored in the memory means.

Preferably, access to at least some of the intelligent processors is limited to prescribed memory parts. The particular intelligent processors for which access is limited can be selectively selected.

Preferably, the memory elements are addressed by content rather than by location.

Preferably, the memory devices can be accessed substantially simultaneously by at least some of the intelligent processors, including the management devices, supplementing information therefrom. The particular intelligent processors, which must have access to the memory members, can be selectively selected.

Preferably, the memory means includes a main memory for storing persistent information and an active memory for storing transition information.

Preferably, main memory can be accessed substantially simultaneously by the controllers and selected other intelligent processors, and information can be supplied therefrom and from the active memory.

Preferably, the active memory can be accessed substantially simultaneously with accesses to the main memory by the controllers, information being supplied therefrom.

Preferably, the main memory comprises an array of the memory elements which are interconnected to allow independent and simultaneous access to it by a number of intelligent processors operating in parallel.

Preferably, the controllers include administrators for controlling and administering the basic operation of the system taking into account some of the information related to its functions and stored in memory, and executive controllers to monitor the overall operation of the system , checking and administering all information stored in the memory means.

Preferably, the administrators may monitor the intelligent processors and couplers for coincidences and maintain awareness of the operational state of the system, and control a communication of selected information between the intelligent processors and the couplers.

Preferably, the administrators may also cooperate with the intelligent processors, the memory members and the executive controllers to resolve the accidents.

Preferably, the administrators may rank the execution of their tasks hierarchically in accordance with the corporate office.

Preferably, the executive controllers may selectively interact with the intelligent processors, the memory members, and the recorders for coincidences affecting the ability of the executive controllers to perceive, as provided by their ability to access all information within the memory members, resolve and monitor the operation of the system.

Preferably, the linkers include a channel device for directing certain types of information supplied to the system directly to the administrators and to convey other types of information directly to other intelligent processors in a manner, the other types of information still being passed by the administrators can be investigated.

Preferably, the active memory includes a short-term memory and an iconic memory, the short-term memory being allocated to: (i) temporarily storing short-term transition information for checking and use by the executive controllers; (ii) supplying to the main memory some transition information selected by the executive controllers, thereby converting the selected transition information into persistent information; and (iii) disappearing other transition information, which is irrelevant to the executive controllers, over a short period of time; and the iconic memory is for: (i) temporarily storing transitory transition information from the administrators for checking and selective use by the executive controllers; (ii) supplying to the short-term memory some transition information selected by the executive controllers, thereby converting the selected transition information into a short-term transition information; and (iii) disappearing other transition information, which is not of interest to the executive controls, upon the expiration of a transit period, which transit period is much smaller than said short period.

Preferably, one or more of the intelligent processors includes means for performing the following tasks: (i) processing graphic elements for generating and displaying graphic elements; (ii) an identity recognition processing for decoding an encoded input signal for identity recognition; (iii) an output processing for performing an intelligent processing of information for output purposes, transmitted through the interfaces; (iv) an input processing for performing an intelligent processing of information for input purposes received via the interfaces; (v) a telecommunications processing for controlling bidirectional communications outside the intelligent device system.

The intelligent processors may be able to perform other tasks besides the above tasks (i) to (v).

The invention will be explained in more detail with reference to the accompanying schematic drawings, in which the components of the system are arranged according to an architecture that mimics that of the human brain.

As indicated in the drawing, the cognition system 11 generally includes a number of intelligent processors, including the processors A, which are involved in specific tasks and controllers B, memory members C, interfaces D and (not shown) areas of cooperation between the intelligent processors A. The couplers D connect the system to a series of external devices E.

The intelligent processors A and B each include a microprocessor and a local resident memory to house "firmware" and application "software", which control the operation of the processor, and perform its required processing functions according to the "firmware" and application "software" instructions.

In the embodiment contemplated here, processors A are operatively arranged in graphics processing means 13, identity recognition means 15, output processors 17, input processors 19, speech synthesis processors 21, speech recognition processors 23, and image recognition processors 25.

The processors A, which provide graphic processing means 13, primarily serve to process, generate and display graphic information for output to suitable graphic output devices at E. This is done in accordance with a computing device program which provides suitable algorithms for contains the processor and is stored in the "firmware" 47 of the assigned system. Where necessary, the processor 13 may immediately access a permitted portion of the stored information memory means C required by the processor to perform its task.

The processors A, which provide identity recognition means 15, primarily serve to decode an encrypted input signal, such as a security card, a fingerprint, an identification kit, etc. for identity recognition. These processors again have an arithmetic program, which contains suitable algorithms stored in "firmware" 47 assigned to it, and has immediate access to a permitted portion of the memory means C when needed. The output processor 17 serves to perform an intelligent processing of information for output purposes, which is to be transferred via the coupling members D to an external device E. As with previous processors, this processor has an arithmetic program, which contains algorithms stored in "firmware" 47 assigned to it, and has instant access to permitted portions of the memory members C, when needed.

The input processor 19 serves to perform intelligent processing of information for input purposes received via the couplers from an external device E. Like the previous processors, the input processor has a computing device program containing algorithms stored in "firmware1" 47, which is assigned to it and has instant access to allowed portions of the memory members C, when needed.

The functions of the other processors 21, 23 and 25 are self-explanatory and, as with the previous processors, they each have a computing device program, the algorithms of which are stored in dedicated "firmware" 47, each of these processors having instant access to permitted parts of the memory means C when necessary.

A special telecommunications processor 45 also forms an intelligent processor and is located outside the system as one of the external devices E. The basic function of this processor is to control bidirectional communications between the system and an external device which is intelligent. Accordingly, the processor processes protocols and communicates with the other processors and the memory devices through the controllers.

The memory members comprise a series of memory elements arranged in prescribed locations to store information therein.

The prescribed locations of the memory members are split into discrete memory parts, which are generally related to the tasks performed by the intelligent processors A. Therefore, information relevant to one task or another task to be performed by an intelligent processor is stored in the appropriate memory portion to simplify the relational arrangement of information in the memory means.

The memory means includes a main memory and an active memory. The main memory includes a long-term memory 27 for storing ever-present information, and the active memory includes a short-term memory 29 and an iconic memory 31, both of which are capable of storing transition information for different periods of time. A resident memory is provided by the "firmware" 47.

The long-term memory 27 has a construction, more particularly characterized in that parallel processing is simplified. In addition, the memory is a high density read / record memory having memory elements interconnected in a matrix. The memory elements are interconnected in such a way that simultaneous addressing by a number of different processors A and B is possible. Information is stored in the prescribed locations of the memory elements in a relational manner such that each prescribed location contains information arranged therein in a relational manner. Therefore, the addressing of a memory element is done by an intelligent processor according to content rather than location. The long-term memory 27 allows the retention of information to form a knowledge base, which is conditionally accessible to the different processors A and selectively accessible to the controllers B.

The memory means C may be implemented in suitable media capable of acting as a storage element. For example, the memory elements can e.g. consist of magnetic media, which can be read or recorded by a scanning head, or the elements may include solid state electric charge storage devices which can be addressed by electronic means. Furthermore, the memory elements can be implemented in new forms of memory technology, such as laser memories or the like. It is clear, however, that the memory elements should be interconnected in such a way as to allow simultaneous addressing of two or more memory elements by a number of processors. Therefore, memory structures that allow parallel memory access are used instead of structures that allow only serial memory access. In the case of magnetic and laser memory media, this can be achieved by using a number of scan heads, and in the case of solid state memory media, this can be accomplished by a matrix addressing structure, which can be three-dimensional for the purposes of the embodiment contemplated here. preferred structure.

Couplers D essentially include an information channel device 33, and input / output gates 39 to gate information externally to and from the system. Thus, ports 39 are connected to external devices E, such as output devices 41, input devices 43, and the dedicated telecommunications processor 45. The output devices 41 can be displays, printers, digital control output devices, local status indicators, and the like.

The input devices may consist of local interactive input devices, analog input devices, digital input devices and the like, and the telecommunication processor 45 may include receive and transmit circuits for connection to various communication protocols, including both asynchronous and synchronous protocols, such as RS232, 20 mA current coupling device , RS422, BYSYNC, DDCMP, HDLC and the like.

The channel device 33 is in the form of an interactive interface, which supplies selected information received by the interfaces D directly to suitable intelligent processors A and B.

The management members B comprise two executive parts: administrators or an administering device 35 and executive controllers or an intelligent device 37. The administering device 35 and the intelligent device 37 are special intelligent processors, which enable the management members to perform the entire operation of manage the system by distributing the management task among its subordinate parts in a hierarchical manner.

The administering device 35 performs a relatively higher level of processing than the processors A and is essentially in the form of a reticular activation system, which coordinates all input and output events in a hierarchical manner. In addition, the administra- tor essentially checks and administers the basic communication operations in the system. The intelligent device 37 provides the highest order of intelligence of the system and has the capability of overseeing the operation of the system and resolving the coincidences therein taking into account information stored throughout memory C. The functions of both the administering device and the intelligent device are resp. determined by each of the associated resident e "firmware" and may be obtained using conventional "software" development methods.

Areas of cooperation between the intelligent processors include any appropriate means through which or through which communications may be conducted. The organs may e.g. consist of rails along which information can be transferred from one processor to another in order to allow instant communication between processors interacting in this manner. Thus, one processor may have a number of collaboration areas to allow a number of processors to share resources when performing a task.

From the above it appears that the relative mutual cooperation between the various components of the system is of high order and is structured in such a way that parallel processing at optimum speed is simplified. Therefore, the intelligent processors A and B are configured such that each processor has direct instant access to each relevant memory element therefor in the long-term memory 27. As indicated graphically in the schematic, this access is controlled by the "firmware" of the processors, permanently integrated, as symbolically shown at 47. In addition, any task A processor A may interact with the admin device 35 and the intelligent device via a reticular communication network 49, represented by the dotted areas in the drawing. Long-term memory 27, as previously described, can be accessed by any of the processors A and the intelligent device 37 via the "firmware" 47. In addition, the long-term memory can be accessed by the intelligent device. 37 and the administering device 35 via the reticular communication network, which has a direct access route via the short-term memory 29 and the iconic memory 31 to the long-term memory via the respective paths 50 and 51. Selected memory elements of the long-term memory are extracted from the short-term memory 29 supplied, as determined by the intelligent device 37, the task-related processors A and the administering device 35.

The short-term memory 29 is capable of direct interaction with the intelligent device 37 alone and conditional interaction with the recording device and the processors A. The short-term memory 29 essentially comprises an erasable memory serving for temporary storage of short-term transition information from the iconic memory 31. This information is only stored in the memory unit for relatively short periods of time for control and selective use by the intelligent device when the latter deems it necessary. Therefore, transitional information stored in the short-term memory 29 finally decreases after a short period, so that if the intelligent device 37 has decided not to supply the long-term memory 27 with this information, the information from the short-term memory unit is eliminated via the path represented by arrow 52 at the expiration of the short period. Conditional access to the short-term memory for the system recorder 35 and the processors A is obtained via the paths 51, which are connected to the reticular communication network 49 via the iconic memory.

The iconic memory 31 is again able to interact directly with the intelligent device 37 alone and conditionally interact with the admin device and processors A, but is served by information supplied thereto by the system admin device 35. The iconic memory 31 serves to temporarily store transition information for a particularly short period of time for selection by the intelligent device 37 when the latter values it. Thus, the iconic memory includes a first in / first out status register, which holds information during a transit period, which period is much smaller than the short period of the short-term memory 29, before this information dies out and is discharged from the memory path represented by the arrow 53. The intelligent device 37 therefore controls the iconic memory 31 when the device 37 appreciates it and determines an information element therein that is relevant to the system. The intelligent device 37 supplies information to the short-term memory 29 as it deems necessary for further consideration.

The coupling members D cooperate with the administering device 35 or with the processors A. A direct mutual cooperation with the administering device is obtained only via the ports 39 with regard to certain types of information which are transmitted or received via the path 55. An indirect mutual cooperation with the administering device 35 takes place via the channel device 33 with regard to certain types of information received from the ports 39 via the path 57, which information is intended to be supplied to a processor. This indirect mutual cooperation is obtained by the path 59, which can be received between the channel device and the admin device 35, via which selected information selected by the admin device is received. In addition, all output information from the system is sent via the path 55 to the input / output gates 39 and selected input information for the system or is received via paths 55 or 57, depending on the predetermined nature and the importance of the information type.

The channel device 33 acts as a means for supplying input information from the coupling members D to the administering device 35 and / or suitable processors A. The system administrator 35 performs most of the basic administration tasks of the system and interacts with most components of the system. Therefore, its administration tasks are highly assigned, performing four main functions: (i) checking processors A and channel device 33 for coincidences and maintaining awareness of the operational state of the system; (ii) communicating selected information between processors A and couplers D; (iii) conditionally interacting with processors A, the iconic memory 31, the short-term and long-term memories 27, 29 and the intelligent device 37 to resolve the coincidences; and finally (iv) hierarchically ordering the execution of its tasks according to the urgency of the required action.

In the case of a cooperation with the processors A, the memories and the intelligent device, this is done via the reticular communication network 49. However, in the case of the channel device 33, a different type of mutual cooperation is present, whereby information is passed through the channel device. , is checked and if it is believed to be of interest for consideration by itself or the intelligent device, it is copied from the channel device through the path 59 to the admin device 35.

When the system administrator 35 recognizes an accident, it can rank the processing of the accident in a hierarchical manner with respect to other tasks to be accomplished thereby and, if necessary, resolve the incident by accessing the respective processor (s), the memory and / or the intelligent device 37 via the reticular communication network 49. In addition, the administering device 35 can carry certain information which it acquires from its checking and administering tasks, at its discretion, for examination by the intelligent device, by supply this information directly to the iconic memory unit 31.

The intelligent device 37 is the head of intelligence in the system and is capable of selective interaction with all processors A, all memory devices C and the admin device 35. This allows the intelligent device to resolve coincidences that require knowledge of the entire operation of the system and to provide information for minor management decisions. Therefore, the intelligent device 37 is in a better position for resolving such accidents than the administering device 35.

The primary advantage of the invention, as provided by the embodiment contemplated herein, is that the system defines an architecture that allows a level of complex deductive reasoning to be provided by artificial means of interpreting and responding to a wide range of number and complex set of events. The system achieves this by using a very fast-acting group of integrated and parallel processors with fast parallel access to a large system of stored information, logic algorithms and management tasks according to a highly ordered executive task assignment and delegation structure. The high processing speeds are achieved by arranging the processing members in a structure that allows parallel processing to be performed, where each processor can be assigned a certain task to be performed simultaneously or in parallel with the other processors .

In order to further increase the speed in those cases where a processor requires access to the main memory, the addressing of the memory by an association with the content of the information and because the information storage in the main memory is organized according to the content instead of by chronological order or the like. In this way, a processor can directly target the memory element containing the searched information by interacting with the content of the information, rather than a series of steps by outputting a large amount of unrelated information until the desired information is located.

A further consideration for the high speed lies in the fact that each processor should be able to obtain the searched information immediately instead of waiting in a queue. Therefore, by using the long-term memory structure considered here, simultaneous access to memory elements is possible, thereby avoiding competitive access with other processors.

In order to simplify communication between the processors, the memory and management bodies, a symbolic language is preferably used. In addition, the various functions and tasks of the system are symbolically coded in order to simplify a reference to them during communication. Therefore, the memory requirements using a high-level symbolic language are small, but the output speeds are high.

In the contemplated embodiment, the various algorithms of the processors are written as symbolic programs, which serve to operate the processors according to the function or task they are to perform. Therefore, these programs are stored in the respective "firmware" 47.

Finally, in order to coordinate the processing of the system at high speed, it is necessary to use a highly ranked and structured executive task assignment system provided by the above-described controllers.

It is clear that the invention is not limited to the above-described particular embodiment. More specifically, the particular functions or tasks performed by the processors are not necessarily limited to those described here, but may also include other tasks necessary to perform for a particular application. Furthermore, different tasks can be assigned to the same processors without having to change the system, allowing a single device to be used for a number of different tasks and still being able to maintain optimum operation.

Claims (18)

Knowledge system for managing and controlling a number of complex tasks using parallel processing, characterized by: a number of discrete intelligent processors, each capable of performing specific tasks; memory means intended for receiving and presenting information for examination by an intelligent processor to determine the storage of the information, said memory means comprising a series of memory elements arranged in prescribed locations for storing the information; means for associating one intelligent processor with another by enabling direct communications between them; and input and output information interfaces to or from the system, the intelligent processors comprising controllers for organizing and directing that information to the memory devices received from the interface devices in the memory devices, taking into account a knowledge of the system, and organizing and building connections between the processors and the couplers. Knowledge system according to claim 1, characterized in that the information is stored relationally in the prescribed locations of the memory members. Knowledge system according to claim 2, characterized in that the memory means are split into discrete memory parts, which are related to the tasks of the intelligent processors, whereby information relevant to one task or another task is converted into a suitable memory part stored to simplify the relational arrangement of information stored in the memory means. Discovery system according to claim 3, characterized in that the access of at least some of the intelligent processors to prescribed memory parts is limited. Knowledge system according to one of the preceding claims, characterized in that the memory elements are addressed on the basis of content instead of on the basis of location. A knowledge system according to any one of the preceding claims, characterized in that the memory means can be accessed substantially simultaneously by at least some of the intelligent processors, including the management means, and information is supplied therefrom. Knowledge system according to any one of the preceding claims, characterized in that the memory means are provided with a main memory for storing permanent information and an active memory for storing transition information. Knowledge system according to claim 7, characterized in that the main memory can be accessed substantially simultaneously by the controllers and selected other intelligent processors, and information can be supplied therefrom and from the active memory. An access system according to claim 7 or 8, characterized in that the active memory can be accessed by the management means substantially simultaneously with accesses to the main memory, the information being supplied therefrom. A knowledge system according to any one of claims 7-9, characterized in that the main memory comprises a matrix of the memory elements which are interconnected to enable independent and simultaneous access thereto by a number of intelligent processors operating in parallel. A notification system according to any one of the preceding claims, characterized in that the management bodies are provided with registration means for controlling and administering the basic operation of the system, taking into account part of the information related to its tasks and which is stored in the memory devices, and executive controllers for controlling and administering the overall operation of the system and taking into account all information stored in the memory devices. Discovery system according to claim 11, characterized in that the administrators can monitor the intelligent processors and the couplers for coincidences and maintain the awareness of the operational state of the system, and a communication of selected information between the intelligent processors and the couplers control. A notification system according to claim 12, characterized in that the administrators are also able to interact with the intelligent processors, the memory members and the executive controllers for solving the accidents. A notification system according to any one of claims 11 to 13, characterized in that the administering means are able to rank the execution of the tasks thereof hierarchically according to the urgency of the operation. An acquaintance system according to any one of claims 11 to 14, characterized in that the executive controllers can selectively interact with the intelligent processors, the memory members and the recorders for accident solving, the acquaintance of the executive controllers being provided by its ability to access all information within the memory devices is required, and to be able to monitor the operation of the system. A notification system according to any one of claims 11 to 15, characterized in that the coupling means are provided with a channel device for directly supplying certain types of information which are supplied to the system to the administering means and directly supplying other types of information. to other intelligent processors in a manner in which the other types of information can still be examined by the administrators. Notification system according to any one of claims 11-16. depending on one of claims 7-10, characterized in that the active memory comprises a short-term memory and an iconic memory, the short-term memory serving for: (i) temporarily storing short-term transition information for the control and use by the executive control bodies; (ii) supplying to the main memory any transition information selected by the executive controllers to thereby convert the selected transition information into persistent information; and (iii) eliminating other transition information that is not of interest to the executive controllers during the expiration of the short period; and the iconic memory is for. * (i) temporarily storing transitory transition information from the administrators for control and selective use by the executive controllers; (ii) supplying to the short-term memory a portion of the transition information selected by the executive controllers to thereby convert the selected transition information into short-term transition information; and (iii) eliminating other transition information not of interest to the executive controllers during the expiration of a transit period, which transit period is much smaller than said short period. Knowledge system according to any one of the preceding claims, characterized in that the intelligent processors are provided with means for performing one or more of the following tasks (i) processing of graphic elements for generating and displaying graphic elements; (ii) an identity recognition processing for decoding an encoded input signal for identity recognition; (iii) an output processing for performing an intelligent processing of information for output purposes, transmitted through the interfaces; (iv) an input processing for performing an intelligent processing of information for input purposes received via the interfaces; (v) a telecommunications processing for controlling bidirectional communications outside the intelligent device system.