SU577669A1 - Voltage-to-number converter - Google Patents

Description

one

The invention relates to computing and can be used to convert voltage into a code with a constant relative error.

A voltage converter is known in the code containing a comparison device, a decoder, an adder, in which the fluctuation of the relative error is two.

However, the device has a large fluctuation in relative error.

A voltage converter is known in the code containing a sensor for a voltage to be converted, the output of which is connected to the first input of the comparison device, the second input of which is connected to the output of the code converter in a voltage of the order and the output to the first input of the control unit whose second input is connected to the output of the pulse generator, the first output of the control unit is connected to the input of the counter, the second output is connected to the first input of the adder, the outputs of the counter through the decoder are sourced to the first input of the code converter into voltage ka, the second entrance of which is connected

output converter code to

the voltage of the mantissa, the first | input of which is connected to the output of the source of the reference voltage, and the second input - to the first # 1 output of the adder 12.

The aim of the invention is to obtain a normalized floating point code.

This is achieved in that a voltage converter into a code comprising a voltage converter, a comparison device, a code converter for order voltage, a shoe converter for mantissa voltage, a reference voltage source, a converter, a control unit, a pulse generator , the counter, the block of elements AND and the register of the mantissa imprints are entered, the first inputs of the element AND are connected to the outputs of the higher bits of the supervisor, the second inputs of the element I are connected to the third output of the control unit, the outputs of the element AND are connected from the input and increments register mantissa, the first output control unit - a control input increment mantissa register, and outputs register information increment mantissa - with respective adder inputs.

The drawing shows a diagram of the device.

The voltage-to-voltage transform into the code contains the device 1, the comparison, in which one input is connected to the output of the converter 2 of the code in the order voltage, the second input is connected with the sensor 3 of the voltage to be converted and the output - c. the control unit 4, which is connected to the pulse generator 5, the control unit 4 is connected to the register 6 of the mantissa increments, with the meter 7, the adder 8 and the element AND 9, the inputs of the element And are connected to the R higher bits of the adder 8, and the outputs from the corresponding bits of the register 6. The outputs of the register 6 are connected to the inputs of the adder 8, the output of which is connected to the input of the converter 10 of the code to the voltage of the mantissa, the analog input of which is connected to the source 11 of the reference voltage, The outputs of the counter 7 are connected to the input of the decoder 12y pin code to The second is connected to the inverter 2.

The voltage converter in the code works as follows.

Before starting work, the code 00 is set on the counter, and on the adder 8 a code corresponding to 10000.0000 (see the table of numerical equivalents) The code of the mantissa adder is fed to the converter 10, where it is converted into the sample voltage, which is fed through the converter 2 device 1 and compared with input. If the converted voltage is more than the reference voltage, then block 4 transfers the contents of the upper bits of the adder 8 to the corresponding bits of the register 6, and also provides the summation of the contents of the adder 8 and register 6, as a result of the cyr-sMBTOpe mantissa code 10001 0000 (see table),

Next, the new value of the reference voltage is compared with the converted one, then the transfer of the contents of the higher bits of the adder 8 (10001) to the register B and the summation of the contents of the adder 8 and

register 6, with the result that the adder 8 has a Vits code 1001 00001 until the moment when on the sump 8 there will be a code 11110 1110.

At the same time, after the transfer of the code 11110 to the register 6 and its summation with the contents of the adder 8, the code 100000 1100, i.e. the overflow trigger: the mantissa adder is set to one, causing block 4 to add unit E to counter 7 and to shift the contents of adder 8 to the right by one bit.

Further, the process is repeated analogously, with the only difference that the voltage from converter 10 will be transmitted through converter 2, providing a transmission coefficient that differs from the previous one two times.

After the value of the reference voltage exceeds the value of the voltage to be converted, the block 4 stops the converter 2 from the signal of the device 1. At the same time, the mantissa code is fixed on the adder 8, the code of the order of the linear numerical equivalent is fixed on the counter 7, and together on the counter 7 and Regisre 6 (excluding most significant bit) is the logarithmic code of the voltage to be converted.

Claims (2)

The use of a voltage-to-voltage converter allows coding to be made with a relative error, the magnitude of the fluctuations of which can be varied by changing the bit size of register 6, increasing the size can be reduced. The numeric equivalent is provided in floating point form with a normalized mantissa, and the input information in the digital computer is greatly simplified and quickened. In addition, replacing the mantissa increment counter with the increment register of the mantissa in the proposed device significantly simplifies the converter circuit and reduces the conversion time The claims of the voltage converter in the code containing the sensor voltage to be converted, the output of which is connected to the first input of the comparator, the second input which is connected to the output of the code converter, the voltage is of the order, and the output is connected to the first input of the control unit, the second input is connected to the output of the pulse generator, the first output of the control unit is connected to the input of the counter, the second output to the first input of the adder, the counter outputs through the decoder is connected to the first input of the code to voltage converter of the order, the second input of which is connected to the output of the code converter to the mantissa voltage whose first input is connected to the output of the reference voltage source and the second With the first output of the adder, characterized in that, in order to obtain a normalized floating point code, the block of the AND elements and the increment register of the mantissa are entered into it, the first inputs of the block of the AND elements are connected to the outputs of the senior bits of the adder, the second inputs AND block with the third output of the control block, outputs of the AND block of the elements connected to the inputs of the increment register of the mantissa, the first output of the control block with the control input of the increment register of the mantissa, and information outputs of the increment register Tisza - with relevant sukmatora inputs. Sources of information received attention during the examination: 1. USSR author's certificate 428546, cl. H 03 K 13/17, 10.05.72. 2. Author's certificate of the USSR 486471, cl. H 03 K 13/17, 20.04.73.