SU964619A1 - Lingvistic terminal - Google Patents

Description

(5) LINGUISTIC TERMINAL

The invention relates to automation and computing and is intended for two-way data exchange with the main means of processing information. A portable interacting terminal is known, which contains an alphanumeric indicator for visual presentation of transmitted and received information, an information memory for storing at least a part of the transmitted and received information and connected by a Q indicated indicator, a keyboard for entering information controlled by one hand 1 3 However, this terminal cannot effectively provide I / O to linguistic variables described by vague sets. . The closest in technical essence to the present invention is a device for input / output of information, comprising a data receiving unit, a dialing unit, a shift register, a memory unit, a data display unit, interface blocks with an information receiver, a synchronization unit, a switch, two buffer register, three triggers, elements AND and OR, and the switch inputs are connected respectively to the outputs of the receiving and data sets and the shift register output, the switch output is connected to the input of the first buffer register, the output of which connected via the I and trigger schemes and the input of the second buffer register, the output of which is connected to the inputs of the interface units, with information receivers and with the shift register, which is also connected to the information display and memory blocks. The disadvantage of the known input / output device is limited functionality, in particular, it is impossible to introduce linguistic variables consisting of vague utterances, as well as to produce a preliminary processing of current linguistic information. The purpose of the invention is to expand the scope of the applied device by using composite linguistic variables. The goal is achieved in that a device comprising a data receiving unit, an information set unit, a first memory unit, a display unit and a synchronization unit whose output is connected to the first inputs of the display unit, the first memory unit, the data receiving unit and the input of the set unit information, the output of which is connected to the second inputs of the display unit, the first memory block, the data receiving unit and the first input of the synchronization unit, the output of the data receiving unit is connected to the third inputs of the first memory unit and the display unit, the fourth the input of which is connected to the output of the first memory block, the second input of the synchronization block is the first input of the device, the third input of the data receiving block is the second input of the device, the second memory block and the logic block are entered, the first input of which is connected to the output of the synchronization block and the first the input of the second memory block, the output of which is connected to the second input of the logic unit and the fourth input of the first memory block; the fifth input of which is connected to the output of the logic unit, the third input of which is connected to the second input oro th block of memory and a second input of the pen unit Vågå memory whose output is connected with the input logical block .chetvertym. . The logic block contains the first, second, third and fourth registers, the first, second and third switches, the comparison block, the first and second decoders, the memory block, the first and second blocks of AND elements and the block of OR elements, the first input of which is connected to the output of the memory block. The first input of which is connected to the output of the first decoder, the input of which is connected to the first input of the first register, the output of which is connected to the first input of the first switch, the output of which is connected to the first inputs of the comparator, the second register and the second input ohm of the OR block whose third input is connected to the output of the second switch and the second input of the comparison unit, the output of which is connected to the first 94 input of the first block of AND elements, the second input of which is connected to the first input of the second switch, the second input of the second register, the second input the first switch, the first input of the third switch, the first input of the third register, the second input of the first register, the second input of the memory block and the output of the second block of And elements, the first input of which is connected to the output of the second desh and the first input of the fourth register, the output of which is connected to the second input of the second block of AND elements, the output of the third register is connected to the second input of the third switch, the output of which is connected to the third inputs of the comparison block, the first and Btoporo registers and the fourth input of the OR element block, the output of the first AND block is connected to the third input of the third switch and the second input of the second switch; the output of the second register is connected to the third input of the second switch; the output of the OR block is the output The second input of the fourth register is the first input of the logical block, the input of the first decoder is the second input of the logical block, the input of the second decoder is the third input of the logic block, the second input of the third register is the fourth input of the logic block. FIG. 1 shows a linguistic terminal block diagram; in fig. 2 - the same, the second memory block; in fig. 3 - the same logical block. The device contains an indication unit 1, a unit 2 of a set of information, a first AND a second unit 3 and a memory, a logic unit 5, a unit. 6 outputs and a data reception unit 7, a synchronization unit 8, a communication bus 9, 10 indications, an indication control unit 11, a sign maker 12, a keyboard 13, an encoding unit H, an interface unit 15, a memory control unit 16, a ROM 17, drive 18, control block 19, decoder 20, counter 21, decoder 22, switch 23, drive 2, OR element 25, trigger 26, AND elements 27, OR element 28, And element 29, buffer register 30, switch 31, block 32 comparison, block of elements AND 33, buffer register 3, switch 35, register 36, switch 37, decoder 38, memory block 39, block to elements OR 0. control re5 .9 gistr 4l, decoder 2, block of elements AND tS. The display unit is designed to display the transmitted, received and service information, the unit provides the display in alphanumeric and verbal form of the necessary information. The display panel 10 provides the display of the necessary alphanumeric and verbal information. The former forms, on the display panel, the necessary characters and combinations of alphanumeric characters or words according to the codes that arrive at the control nodes. The control unit 11 is designed to receive input information, as well as to coordinate it in time and PB levels with other terminal blocks. Unit 2 of the set of information is intended for a set of names of linguistic terms, alphanumeric and service information for management and input to the terminal. The block consists (Fig 1) of the keypad of the input and control information set 13 of the coding unit 14 and the interface block 15. Coding unit 1A consists of encoders and performs Coding of all input information into corresponding codes. The conjugation unit 15 is a register that receives the code from the block coding coders and outputs it to other blocks of the terminal. The memory unit 4 is designed to store the primary values of linguistic terms. The block stores primary linguistic terms in various basic sets that are necessary to control this process or object. In addition, these primary terms are used to derive compound linguistic terms, the need of which determines the process or object of control to adequately manage them. Block 4 works as follows. From the set of information set 2, the decoder 20 receives the code of this basic set, which selects a memory element in the accumulator, and counter 21 receives the code of the primary linguistic term, which is the first address of the given part of the memory element. or the address of a given linguistic term for a given basic set. Signal

Claims (2)

stretching or concentrating operation code. After decrypting the code through the AND circuit, the selection l96 from the output of the decoder 20 sets the trigger 2b. A single state, which, using the circuit 29, allows the clock frequency to flow to the counter 21, which generates the subsequent addresses of the memory for choosing the primary linguistic terms. The code of the counter 21 is decrypted by the decoder 22. And through the switch 23 enters the drive. The outputs of the memory elements are combined via the OR circuit 25. When the last address of each memory section is reached, all the elements of the signal from the switch 23 through the circuit AND 27, OR 28 reset the trigger 29 and the counter 21. The read value of the primary linguistic term through the circuit OR 25 enters the output device. The memory size of each element is determined by the specific values of the base set and, in general, for different processes or objects of control, is different. The use of a memory block with primary values of linguistic terms makes it possible to significantly simplify the process of forming primary linguistic terms due to the absence of complex arithmetic logic units and microprograms for performing operations in them. The memory unit 3 is intended for intermediate storage of the input and output values of linguistic terms. Logic block 5 is designed to perform basic operations on the meanings of primary linguistic terms in order to obtain linguistic compound terms that the operator operates in the control process. These operations include the following: inversion, conjunction, disjunction, implication of equivalence, concentration and stretching. The memory unit 39 is used to perform concentration and expansion operations and consists of two sections. The memory unit 39 is designed to store, respectively, the value, where / L is the degree of membership, which takes a value in the interval (0.1) and is recorded with a resolution of 0.01. Consider the work unit. Suppose that a decoder 2 has arrived at the decoder 2. The value of / x goes to the decoder 38, and after decryption, the 9 n value of the / X, is selected, which goes to the output of the block, i.e., the value of / x - is used as the value address. The use of such a principle of performing these two operations allows to increase the reliability and speed of performance of these operations due to the absence of a complex microprogram and operating part. The number of paired memory cells used to store the value of / c or / g is 100 bytes. When performing the remaining operations, the main control signals form together the register 41 and the decoder 2 using the block of elements 3. These signals are sent to all elements of the block. Therefore, the process of functioning will be considered in order of passing information. Inversi operation. This is the easiest operation. When it is executed, the contents of registers 30 or 3 through the corresponding switches and block of elements OR 0 are output to the output in the inverse code. The Conjunction, Disjunction and Implication operations are generally the same. At the beginning, the contents of registers 30 and 3 in the forward or inverse codes via the switches 31j. 35 arrive at comparison unit 32. After comparison, according to the signals formed in the block of elements AND 33, which arrive at the switches 31 and 35, the contents of the register 30 or 3 in the forward or inverse code are output-output, depending on the operation performed. Operation Equivalence is the most complex and is performed in three stages. At the first stage, the contents of registers 30 and 3 through the switches 31 and 35 in the forward and inverse codes, respectively, arrive at the comparison unit. As a result of the comparison, the highest value through the switch 31 or 35 is fed to the Zb register. At the second stage, the comparison block receives the contents of registers 30 and 3 through switches 31 and 35 in the inverse and direct codes, respectively. As a result of the comparison, the highest value remembers register 3, i.e., if the contents in the inverse code of register 30 are greater than the contents of register 3 3.8 3, then the contents of register 30 in inverse code are written to the register. In the final third stage, the comparison unit arrives; registers 3 and 35 through switches 35 and 37, respectively. As a result of the comparison, according to the output signals from the comparison unit, and using the unit 33, a signal is generated which provides for outputting the smallest of the contained registers 3 and 3B. This completes the operation. The output units 6 and data reception 7 with external devices are intended to be exchanged with the main data processing means. Data reception or output from the terminal is performed asynchronously. Blocks 6 and 7 are designed to match the received and output information of the terminal by levels, in time, and with standard communication devices. The synchronization unit 8 is designed to generate the multi-phase clock signals necessary for the operation of all the nodes and blocks of the terminal. The basis of the block is a multiphase generator, synchronized with the main data processing systems. A linguistic terminal with preprocessing of information is intended for input-output of values of linguistic variables and other information into data processing systems, as well as conversion of the basic blurred set into primary linguistic terms and performing logical operations on primary linguistic terms formed from simple blurred statements to produce composite linguistic terms. terms necessary for this management process. A blurry sentence is a sentence in relation to which one can judge the degree of its truth or falsity at the present time. The degree of truth of each vague statement takes values in the interval (0,1). Examples of vague heights are four small numbers, many cars at a crossroads, this book is very interesting. The degree of truth of the first vague utterance is set to 0.9, the second is 0.6, and the third 9964 0.2. If a and b are some vague utterances, then the composite vague utterances are formed from simple Negative logical operations. M) Conjunctions L min (a, tT) (2) Disjunction a V b max (a, B) (G) Implication a b min (la, b) (4) Stretching DIL (a) a (5) Concentration consensus a (6) Equivalence a b min (check (1-a, b), max (l-ba) (7) Consider the concepts of vague arrogant variables, vague logical formulas and linguistic variables. A vague articulatory variable is called a vague utterance ,, The degree of truth of which can take an arbitrary value from (0.1). A blurry logical formula (x, xj x) () is called: any chat spread is variable and is the constant from (0,0; if A.. (xx ,, x,, .., „) and A (x, k, ..., Xfl) are vague formulas, then applying to them a finite number of times logical operations (7 , 8 V,,, DIL, CON) produces a fuzzy logical formula; there are no other fuzzy logical formulas. The set A (,) is called a blurry set in the base set X if the degree of truth of a blurry statement xA is defined for each heX, denoted by DD (x) / / The degree of equality / x (A, B) of two vague sets is determined by the expression / x (A, B) x (Xd (x) / x. (X;), (8) is a conjunction operation defined by (2 ), which is taken over all hex, is the equivalence operation defined by (7), which is taken for the corresponding pairs of blurry sets A and B. Linguistic variables are sentences formed in a natural or formal language of blurred elements (symbols) The primary linguistic terms are sentences that are basic and various basic terms needed in the control process are newly formed. Suppose that the set X is the number of large integrated circuits (LSIs) laid for manufacturing in one technological process. Let X be a set consisting of 10 LSIs, t, e. 1, 2, 3, 4, 5, 6, 7, 8, 9, JO. In a certain way of choosing a blurry subset A of set X you can form concepts that are the primary values (terms) of the linguistic variable number of LSI } 1%, 0.8 / 2.0.7 / 3.0.6 / 4, 0.3 / 5.0.0 / 6,. can be considered as a small LSI value, a value is sufficient or front displays a blurry subset A., 2 / 3.0,, 0.9 / 5.1 / 6,, 8 / 7.0, and the meaning is many, 3 / 6.0.6 / 7.0.7 / 8.0.9 / 9,,. Using the operation (1), we find the value of a number of the LSI which is not a little linguistic variable. We get 7 -,, 2/2, 0, 3 / 3.0, k / k, 0.7 / 5.0.9 / 6.1 / 7.1 / 8.1 / 9,. As a result of applying the concentration operation (6) to the set A, the degrees of belonging of elements to this set are reduced, and for elements with a high degree of belonging this decrease is relatively small, and for elements with a small degree p. relatively large. For example, applying (6) to the value of A, we get a very small value. we have 5 CON (D), 0, 64/2, 0, 9 / 3.0, Zb / | , 0.09 / 5.0,. The stretching operation is the opposite of concentration. For example, using this operation to a vague set of very few, you can get the value of a little linear term the number of LSI. DIL (A5) A-, 1/1, 0.8 / 2, .0.7 / 3, 0.6A, 0.3 / 5.0 ,. i.e., DIL (CON ()) A. In addition, using other logical operations such as disjunctions, conjunctions, implications, and others over the primary meanings of linguistic terms, one can engender a multitude of different composite linguistic terms necessary to control the process. Consider the operation of the terminal. The terminal has three main modes of operation: Set, Input, Output. Selecting the appropriate mode of operation is carried out using the buttons on the information set node. The interaction of the terminal with external sources and receivers of information is carried out in an asynchronous manner using control signals Call and Receive. In the Set mode, information is pre-processed, i.e., obtaining primary linguistic terms, forming composite linguistic terms, and entering, as necessary, new meanings of the primary linguistic term, as well as clear information in the terminal memory block. . Consider the process of reading primary linguistic terms from memory block k. To accomplish this, it is necessary to type the necessary name of the primary linguistic terminal on the keyboard, for example, a little BIS. This term is typed using two small keys and an LSI. After dialing, in the coding unit H is encoded into the corresponding codes, which, through the software block 15, step into the display unit 1 and the control unit 16. The control unit 11 forwards these codes with the necessary time interval to the signifier 12. The transformer forms the corresponding words, which are indicated on the display unit 10. In the ROM, the code of the LSI word through the decoder 20 and the switch 23 switches the required memory element 2, and the word code is small, which is the initial address of the primary linguistic term in the selected element and goes to the counter 21. After the counter, it goes to the decoder 22, The decoder decrypts the first address of the element of the primary linguistic term, which through the switch 23 enters the first part of this memory element. Subsequent addresses of elements of the primary linguistic term form a counter 21. From the block, the read value of the primary linguistic term enters one of the following blocks: logical 5, memory 3, and output 6, depending on where we need to send the information. The operations performed in a logical block can be divided into two groups. 1. Operations performed on one linguistic term {inversion. concentration and stretching). 2. Operations performed on two linguistic terms (disjunctions, conjunctions, implications, and equivalence). When performing operations of the first group, the value of the linguistic term enters the logical block from blocks 3 or C. When performing operations of the second group, 1/1 linguistic variables are synchronously received from blocks 3 and 4. Operations in the logical block are performed sequentially on each degree of belonging, input constituting a linguistic term. As a result of performing logical operations on primary linguistic terms, we obtain the composite linguistic terms needed in the control process, which are recorded in block 3. The choice of an operation and the value of the linguistic variable is performed using the appropriate keys of the information set block 13. When forming compound linguistic terms, control is provided for the degree of belonging of each element of the linguistic term and an adjustment is possible as necessary. Monitoring is carried out visually using the display unit. Enter Mode In this mode, information is output from the terminal to the data processing system. After pressing the Call key and the name of the value of the linguistic variable on the dial pad, the terminal is ready to issue the value of the linguistic variable. The output is effected from the corresponding part of the block k or the block 3 of the memory. The selection of an element and a part of an element is carried out by a naming code or a linguistic variable. To display information, you must specify the starting address of the memory unit where the information is located, and the amount of information. The issuing unit is controlled by the issuing unit 6, and, as necessary, the information transmitted can be monitored. Output Mode In this mode, the processing results are output from the central information processing system or data from workstations to the terminal. The received information through the reception unit 7 is fed to the recording unit for recording. Reception unit 7 provides reception of information on the Ready signal from the central data processing system or from workstations, transmitting and recording it into the free section of the memory block. The selection of a free memory section is made from the information set block. The use of a linguistic terminal will bring the description of control processes closer to the human language, which greatly enhances the convenience, quality and reliability of control. Claim 1. Linguistic terminal containing 6 jnoK data reception, information set block, first memory block, indication block and synchronization block, the output of which is connected to the first inputs of the display block, first memory block, data receiving block and blog entry information set, the output of which is connected to the second inputs of the display unit, the first memory block, the data receiving unit and the first input of the synchronization unit, the output of the data receiving unit is connected to the third inputs of the first memory unit and the display unit, the fourth input The second input of the synchronization block is the first input of the device, the third input of the data receiving block is the second input of the device, characterized in that in order to expand the field of application of the device by using composite linguistic variables, it has a second memory block and a logic block, the first input of which is connected to the output of the synchronization block and the first input of the second memory block, the output of which is connected to the second input of the logic block and the quarters the input of the first memory block, the fifth input of which is connected to the logic module output, the third input of which is connected to the second input of the second memory block and to the second input of the first memory block, the output of which is connected to the fourth input of the logic block, p. tl and h a2. The device according to which the logical block is the second, the third and even contains the first, the first, the second and the third registers, the switches, the comparison unit, the first and second decoders, the memory block, the first and second And blocks and OR elements, the first input of which is connected to the output of the memory unit, the first input of which is connected to the output of the first decoder, the input of which is connected to the first input of the first register, the output of which is connected to the first input of the first switch, the output of which is connected to the first inputs of the compare module nor, the second register and the second input of the OR unit, the third input of which is connected to the output of the second switch and the second input of the comparison unit, the output of which is connected to the first input of the first block of elements AND, the second input of which is connected to the first input of the second switch, the second input of the second register , the second input of the first switch, the first input of the third switch, the first input of the third register, the second input of the first register, the second input of the memory block and the output of the second block of And elements, the first input of the connected to the output of the second decoder and the first input of the fourth register, the output of which is connected to the second input of the second unit And, the output of the third register connected to the second input of the third switch, the output of which is connected to the third input of the comparison unit, the first and second registers and the fourth input of the element block OR, the output of the first block of elements AND is connected to the third input of the third switch and the second input of the second switch, the output of the second register is connected to the third input of the second switch, the output of the block and the OR elements are the output of a logic block, the second input of the fourth register is 159b, the first input of the logic block, the input of the first decoder is the second input of the logic block, the input of the second decoder is the third input of the logic block, the second input, the third register is the fourth the input of a logical block. ag f 9 Sources of information taken into account in the examination 1. US patent number M005380, cl. G 06 F 3/02, published. 1978. 2. USSR author's certificate No. 519702, cl. G 06 F 3/02, 1972 (prototype),