SU1508285A2 - Sampling/storage device - Google Patents

Abstract

The invention relates to automation and computing and can be used in discrete-analog signal converters and is an improvement of the device according to author N 1401519. The purpose of the invention is to improve the accuracy of the device. This goal is achieved by reducing the switching charges of the separating elements 1.2 connected to the storage element 13, reducing by more than the order of the uncompensated difference of these charges falling on the element 13, as well as reducing the uncompensated leakage current of the elements 1.2 for by keeping them in storage mode, the potential is close to zero. 1 il.

Description

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The invention relates to automation and computing, can be used in discrete-analog signal converters and is an improvement of the device according to the author. St. No. 1401519.

The aim of the invention is to improve the accuracy of the device.

The drawing shows a diagram of the device.

The device contains first and second separating elements 1, 2, first and second compensating elements 3, 4, third - eighth separating elements 5 - 10, third, fourth compensating elements 11, 12, accumulative element 13 on a capacitor, repeater amplifier. 14, the first, the second gated, the third - the sixth current sources 15-20, the information input 21, the control input 22, the information output 23,

The device works as follows.

In the sampling mode, with the appropriate control signal at the device input, the sources 15, 36 form powerful and equal flowing and flowing currents of equal value, which, with equal voltages at the input 21

devices and element 13 open branches from elements 9, 5, 6, 10 and 8, 1, 2, 7, the currents of sources 17-20 are selected several times less than the currents of sources 15, J 6 and the device operation in the sampling mode is not affected . At the output of amplifier Repeater 14, a voltage equal to the input voltage is formed, the potentials on the elements 3, 4 are close to zero and they are closed. When the voltage at the device input 21 changes, for example, when it increases, the voltage at the output of source 16 increases, elements 7, 2 close, and the current of source 16 is diverted to information input 21 of the device. On the element 13, on the anodes of the elements 1.8, the voltage cannot instantly change, therefore the elements 5, 9 are closed, then the source 15 charges the element 13 through the elements 1, 8, the Element 13 is charged before equalizing the currents in the wind in x elements 1, 8 and 5, 9, which will occur when the voltage at the device input 21 becomes equal to the voltage at element 13 and

output 23 of the device. Similarly, the process of the discharge of element 1 by the current of the source 16 goes through the elements 2 7 with a decrease in the voltage to the input

21 devices

In storage mode with an appropriate control signal at the input

22 devices, sources 15, 16 are disconnected; through the branches of elements 5, 9 and 6, 10 the current does not flow due to counter-inclusion of elements 8, 7, the potentials of the cathode and anode of elements 1, 2 change under the action of leaky and The sources of currents 17, 18 flowing in to the unlocking of elements 3, 4, Elements 1, 2 are maintained in the closed state, near-zero potential, formed relative to the potential of the output 23 by elements 3, 4, 11, 12

and sources 17-20. For identical elements 3, 4, 11, 12, the currents of sources 19, 20 are chosen equal and twice as large as the currents of sources 17, 18. Switching charges coming from closing elements 1, 2 to element 13 are equal, are also different when negotiating parameters

The ditch of the elements 1, 2, 3, 4, 11, 12 self-compensate, for example, in the case of the implementation of these elements as part of a monolithic integrated circuit. The device has a very low for diode bridge key elements signal transfer ratio from input 21 to output 23 in storage mode which is determined by dividers consisting of barrier capacitors of elements 5, 9, 8 and 6, 10, 7, output capacitances of gated sources 15, 16, dynamic resistances of elements 4, 12 and 3, 11, output resistance of amplifier repeater 14, load capacitance connected to device output 23, as well as from barrier capacitances of reverse-biased elements 1, 2 and element 13 capacitance , 2, 3, 4, 11, 12, as part of a monolithic IC, good agreement is achieved between these diodes with respect to direct voltage drops and switching charges, which allows for high accuracy of the device operation in a wide temperature range; in addition, the reverse bias of elements 1, 2 in the storage mode is supported

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close to zero and does not depend on the voltage at inlet 21 and outlet 23, which makes it possible to reject the protection diffusion regions of these elements and further reduce the switching charge and leakage currents.

Thus, the accuracy of sampling and storage of the input signal of the device is improved by reducing by more than the order of the switching charge and its non-compensable difference in the separating elements applied to the storage element and reducing the leakage current through several times these items are in storage mode.

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6 Formula of the invention

Sampling device - storage auth. St. No. 1401519, о.т л and h ay - e with the fact that, in order to improve the accuracy of the device, the third and fourth are introduced into it. The compensating elements on the diodes, the fifth and sixth current sources, and the cathodes of the first and The third compensator is connected to the output of the fifth current source, the anodes of the diodes of the second and fourth compensating elements are connected to the output of the sixth current source, the anode of the third diode and the cathode of the fourth compensating element are connected to the information output of the device.

Claims (1)

SUMMARY OF THE INVENTION Sampling and storage device according to ed. St. No. 1401519, distinguishing by the fact that, in order to increase the accuracy of the device, the third and fourth compensating elements on the diodes, the fifth and sixth current sources are introduced into it, and the diode cathodes of the first and third compensating elements are connected to the output the fifth current source, the anodes of the diodes of the second and fourth compensating elements are connected to 15, the sixth current source, the anode of the diode of the third and the cathode of the diode of the fourth compensating elements are connected to the information output of the device.