RU185002U1 - DATA FLOW BUFFERING DEVICE - Google Patents

Abstract

The technical solution relates to information technology. The technical result consists in providing the requirements of the Kotelnikov theorem to the stability of the frequency of polling data sources when generating queries with a random frequency as a result of the poling procedure. A data stream buffering device including a data source, the group of outputs of which is connected via a buffer to the first group of inputs of an input controller connected to a bus, to which an output controller is also connected, the first group of outputs of which is connected to the first group of inputs of a buffer control, and a controlled a generator and counter, the group of outputs of which is connected to the second group of inputs of the input controller and to the second group of inputs for controlling the buffer, and the input is combined with the synchronization input of the source data and is connected to the output of a controlled generator, the group of installation inputs of which is connected to the second group of outputs of the output controller. 6 ill.

Description

The technical solution relates to information-measuring equipment, and can be used in digital control systems for various objects, in particular unmanned aerial vehicles, ground unmanned vehicles and others.

A device for buffering data streams (Patent US 7581072 B2, class G06F 12/00, published. 12/14/2006), which consists of a data source, a computer and a buffer through which the computer is connected to the data source.

A disadvantage of the known device for buffering data streams is the generation of requests as a result of the poling procedure, and as a result, the low stability of the data input frequency, which causes poling noise.

The closest in technical essence of the claimed data stream buffering device (prototype) is a data buffering device consisting of a data source, the output group of which is connected via a buffer to the first group of inputs of the input controller connected to the bus, to which the output controller is also connected, the first group of outputs which is connected to the group of buffer control inputs (patent RU 2475817, class G06F 9/30, published. 02.20.2013).

The disadvantage of the prototype is that requests for data input in it, as well as in the analogue, are generated as a result of the poling procedure, as a result of which it does not provide the required stability of the polling frequency of the data source.

The technical task of the technical solution is to increase the stability of the polling frequency of the data source by coordinating in time the polling frequency of the data source with the frequency of requests for data input generated as a result of the poling procedure.

The specified technical result is achieved by the fact that in the device for buffering a data stream, including a data source, the group of outputs of which is connected via a buffer to the first group of inputs of an input controller connected to a bus, to which an output controller is also connected, the first group of outputs of which is connected to the first group of inputs buffer control, and the device includes a controlled generator and counter, the group of outputs of which is connected to the second group of inputs of the input controller and to the second group of control inputs Ufer, and combined with the data input clock source input and is connected to the output of controlled oscillator, the group setting input of which is connected to the second group output controller outputs.

The essence of the technical solution is illustrated by drawings.

In FIG. 1 is a block diagram of a data stream buffering device.

In FIG. 2 is a timing chart of data entry. FIG. 3 is an explanation of the operation of the buffer.

In FIG. 4 is an explanation of a data source device.

In FIG. 5 shows a block diagram of a controlled generator.

In FIG. 6 is a block diagram of a buffer 3.

To a data stream buffering device, the structure of which is shown in FIG. 1, the data source 1 enters, the output group of which is connected to the input group of buffer 2, the output group of which is connected to the first input group of the input controller 3, the output group of which is connected to bus 4 of the Von Neumann type 5 computer. The Von Neumann type 5 computer, through the bus 4 is connected to the group of outputs of the controller 6 output, the first group of outputs of which is connected to the second group of inputs for controlling the buffer 2, and the second group of inputs is connected to the group of installation inputs of the controlled generator 7, the output of which is connected to the input of the counter Ika 8, the group of outputs of which is connected to the first group of inputs for controlling buffer 2 and the second group of inputs of input controller 3, the input of counter 8 is connected to the input of data source 1.

The data entry timing chart of FIG. 2, includes the axis 9 of the probability density distribution of the time that the Von Neumann type computers access the data source, the time axis 10, the function 11 of the density of the probability distributions of time between the Von Neumann type computers for data input, the mathematical expectation of 12 time between the Von Neumann type computer requests for input data requests 13 generated by Von Neumann type computers for data input, requests 14 for reading data from data source 1, time-varying analog signal 15, slew rate of 16 analog signal Ala 15.

In FIG. 3 illustrates the operation of the buffer, including the address 17 of the cell 18 into which data is recorded, the address 19 of the cell 20 from which data is read;

In FIG. 4 is a block diagram explaining the operation of a data source 1, including an analog data source 21, an analog-to-digital converter 22, a register 23, to the synchronization input of which a controlled oscillator 7 output is connected. The output group of the register 23 forms a group of outputs of the data source 1.

The controllable generator of FIG. 5, the actual generator 24, the generated frequency code register 25, the counter 26, the comparator 27 are included.

To the buffer 3 shown in FIG. 6, the actual RAM 28, the input address demultiplexer 29, the data multiplexer 30, the output address input code register 31 are included.

The device operates as follows.

The input data in analog form is formed at the output of the analog data source 21 itself and, using the analog-to-digital converter 22, is converted into a digital code and, by the synchronization signal generated by the controlled oscillator 7, is entered into the register 23, on the output group of which the data input to the buffer is generated 2. Data on the group of outputs of the data source 1 is formed at the moment when the output of the controlled generator 7 generates a request 14 for reading data from the data source. Managed generator 7 generates requests 14 for reading data from data source 1 with a frequency that is determined by the code entered by the group of installation inputs of the controlled generator 7 into register 25 of the generated frequency code through controller 6 of output from computer bus 4 Von Neumann type 5 at the stage of device setup buffering the data stream. In the process of operation of the controlled generator 7, the actual generator 24 generates pulses with a highly stable frequency, which are counted by the counter 26. The comparator 27 compares the status of the counter 26 and the contents of the register 25 of the generated frequency code. When the state of the counter 26 coincides with the generated frequency code stored in the register 25, a pulse is generated at the output of the comparator 27, which, on the one hand, resets the counter 26, and on the other hand, is the output pulse generated at the output of the controlled oscillator 7.

Requests 14 to read data from the data source 1 from the output of the controlled generator 7 are fed to the input of the counter 8, which generates the address 17 of the cell 18 of the buffer 2, into which data is written from the group of outputs of the data source 1. The data buffer 2 is a random access memory 28 with the separation of data into input and output data. When entering data into buffer 2, the address of the cell to which recording is made is formed using the group of outputs of counter 8. This address is fed to the input of the demultiplexer 29 of the input address. In accordance with the code generated at the group of outputs of the counter 8 at one of the outputs of the demultiplexer 29, a data recording signal is generated in the cell 19 of the buffer 2. In addition, the address 17 of the cell 18 of the buffer 2, generated by the group of the outputs of the counter 8, is input through the input controller 3 and the bus 4 in the computer 5 Von Neumann type.

Data input from buffer 2 through bus 4 into a Von Neumann type 5 computer is as follows. The address of the cell 19 from which data is input is input through the output controller 6 to the register 31 of the output address of the buffer 2. The output code of the register 31 is supplied to the control input of the multiplexer 30, to the information inputs of which the signals from the outputs of the memory cells 28 are supplied. In accordance with with the code entered into register 31, only one of the cells, namely, the memory cell 19 of the RAM 28, is switched with the group of outputs of the buffer 2. The data from the group of outputs of the buffer 2 are input through the input controller 3 and bus 4 in the computer 5 Von Neumann type.

Requests 13 to enter data through the bus 4 of the computer 5 Von Neumann type form software as a result of the poling procedure, so the time intervals between requests 13 are random. The size of the intervals is determined accurate to the distribution density 11. If at the time of the data entry request, the analog signal 15 from the analog data source 21 itself changes in time at a speed of 16, then the deviation from the true value of the signal is determined by the product of the slew rate 16 by the amount of time the deviation of the real request from its mathematical expectation 12. Thus, poling noise is generated. To eliminate poling noise, the data is input into a Von Neumann type 5 computer through buffer 2, while the source of analog data 21 is interrogated with a highly stable frequency generated at the output of the controlled oscillator 7, and with this frequency it is converted into a digital code using an analog-to-digital converter 22 , and then entered into register 23. Data is entered into the computer at random time intervals determined by the poling procedure. The presence of a buffer makes it possible to increase the stability of the polling frequency of the data source by coordinating in time the polling frequency of the data source with the frequency of data input requests generated as a result of the poling procedure, to eliminate the effect of poling noise by fulfilling the requirements of the Kotelnikov theorem.

Claims (1)

A data stream buffering device including a data source, the group of outputs of which is connected via a buffer to the first group of inputs of an input controller connected to a bus, to which an output controller is also connected, the first group of outputs of which is connected to the first group of inputs for controlling the buffer, characterized in that It additionally includes a controlled generator and counter, the group of outputs of which is connected to the second group of inputs of the input controller and to the second group of inputs for controlling the buffer, and the input is combined with the input m synchronization of the data source and is connected to the output of a controlled generator, the group of installation inputs of which is connected to the second group of outputs of the output controller.

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