SU691882A1 - Linear extrapolator - Google Patents

Description

(54) LINEAR EXTRAPULATOR

one

The invention relates to devices used in measurement and response technology for extrapolating functions defined by digital codes of ordinates, with a representation of the result of extrapolates in analog form.

An extrapolator is known that contains three memory cells (each of which contains serially connected registers and a digital-analog converter), a digital-analog block, two delay elements, and five scaling blocks l.

This device has narrow functionality, since it is intended for extrapolation of functions specified only by equally equivalent time codes of ordinates, as well as high complexity of tuning, since with arbitrary block characteristics it is not always possible to configure the device to perform extrapolator functions.

The closest technical solution to the proposed is linear

an extrapolator containing pam5ggi cells, the first output of each of which is connected to the first input of the corresponding digital-analog multiplication unit, the second output of the first one. the memory cells are connected to the input of a digital-to-analog converter, the first inputs of the memory cells are respectively the first, second and third inputs of the extrapolator, and the installation inputs of all the memory cells are connected to the fourth input of the transponder, the fifth, sixth and seventh The input of which is connected respectively to the second analogue and digital-analog blocks of multiplication 2.

Claims (2)

The known device has narrow functionality, since it is intended to extrapolate functions defined only by time-equivalent ordinate codes, as well as low dynamic accuracy, due to the fact that extrapolation is performed only from two counts of the function (the second derivative of ), and the 6th function itself is of a stepwise nature at the site of extrapolation. The aim of the invention is to improve the accuracy of the device and expand its functionality. The goal is achieved by a linear extrapolator containing a linear voltage generator, an inverter and an output adder, the inputs of which are connected directly to the outputs of a digital-to-analog converter, a second and third digital-analog multiplicator blocks, and a choree inverter to the output of a second digital-analog multiplicator unit, a linear output generator of a linear multiplexer, and an output generator of a linear-to-digital multiplexer multiplexer, and an interlocking generator connected to the fourth run of the extruder, and connect its vyi.od to the second ports of the memory cells. The drawing shows a block diagram of a linear extrapolator. Linear extrapolator contains memory memories 1-3, analog converter 4, linear voltage generator 5, digital-analogue multiplication blocks 6-8, inverter 9 and output adder 10, through par 11 11, second 12 and third 13 extrapolator outputs memory cells 1-3 are entered by ordinate codes of the extrapolated function. At the fourth entrance. 14 nocTytiieif andSpaps of the end of the next extrapolation interval. With input 14, the SCHEMyMY installation inputs of all memory locations are 1-3. With the interference of the codes supplied to the fifth IS, the sixth 16 and the seventh 17 xystrypoltor switches, the extrapolator is set up to work with a specified observation time (Meyad time interval first and stored samples of the extrapolated function) and with a $ 1 MHF per square foot. counts. The output of the extrapolator is indicated by the position 18. Each memory cell 1–3 contains sequentially connected register 19 and a digital-analog converter 20. The linear extrapolator works as follows. In the operating mode, the next pulseCoM of the end of the extrapolation interval arriving at the gate 14 clears and starts the generator 5 of the linear voltage and clears the registers of memory cells 1-3 while simultaneously receiving the next ordinate codes of the extrapolated function: through input 11 - the X /} code , in turn 12 - code x, after 82 15 - code Chr. After the termination of non-transient processes, the output of the digital-to-analog converter 4 is set to a value (for example, DC voltage) proportional to the Xp code, and to the output of the generator 5 - a linearly varying linear value of Ug proportional to the ratio tg / At I which is fed to the analog inputs of the converter of 4 memory cells 1–3 (t is the extrapolation time continuously varying from 0 to At). Memory cells 1–3, in addition to storing codes and converting them to analog values, also perform functions of multiplication units. At turns 15–17 digital-analogue multiplication blocks 6–8, codes are received that are proportional to K-, K. and Kg, respectively, to weighting factors. To (these are quickly set up by the extrapolator). In accordance with this, the outputs of blocks 6, 7 and 8 continuously produce analog voltages proportional to the respective 6 X -KO-TZ / A} -Xn.K. summations are a quantity proportional to Thus, the output analogue value Xd is proportional to the extrapolated He-Xp.dUp,. | 4 value of the extrapolated function, given by the digital codes x, Xti. ®Вв88, but After arriving at exit 14 (after reaching t A t) the pulse of the end of the extrapolation interval, the cycle of the extrapolator is repeated. A decrease in the dynamic error when using the proposed extrapolator is achieved due to the fact second derivative. So, the increment value is dx. is defined as XAt + Xy, or after substituting x expressions. Thus, extrapolation is carried out taking into account the second derivative of the function. Increasing the accuracy is optimized because the output value Xfj, which is proportional to the extrapolated function, changes linearly and uninterruptedly in the extrapolish trj | -0-VAi interval. Expansion of functional capabilities is achieved by using unequal counts of the extrapolated function, which leads to the expansion of the field of application of the proposed device. Claims of the invention Linear extrapolator containing memory cells, the first output of each of which is connected to the first input of the corresponding digital multiplexing block, the second output of the first memory cell is connected to the input of the digital-analogue converter, the first passages of the memory cells are respectively the first, second and third the inputs of the extrapolator, and the installation passages of all the memory memories are connected to the fourth input. // o ", - C of the extrapolator, the fifth, sixth and seventh inputs of which are co-dinones, respectively, with the second inputs of digital-analog multiplicators, characterized by the fact that, in order to improve accuracy and enhance functionality, it contains a linear voltage generator, an inverter and an output adder, the inputs of which are connected directly to the outputs of the digital-to-analog converter, the first and third digital-analog multiplicators, and through the inverter to the output of the second digital-analog multiplicator, output a generator ra line voltage coupled to the fourth input extrapolation of the torus, and its output is connected to the second inputs of the memory cells ,, Information sources received into account in the assessment. 1, USSR Author's Certificate fc 373733, cl. Q 06 Q 7/30, 1873. 2. For Me 2425327/24, according to which a decision was made to increase the author's certificate, cl. G 06 O 7/30, 1976,