SU1109908A1 - Three-channel majority device - Google Patents

Abstract

THREE-CHANNEL MAJORITY DEVICE, containing in each channel a resistor, signal source, load resistor, bias source and six diodes, the output of the signal source is connected via a resistor to the first cathode and to the second anode and second cathode anode and third cathode and third cathode the fourth diode, respectively, with the positive and negative outputs of the bias source, the cathode of the third and the anode of the fourth diode are connected to the cathode of the fifth and the anode of the sixth diode and through a load resistor with A common bus which is connected to the input of a signal source, characterized in that, in order to simplify, the anodes of the fifth diodes of the first, second and third channels are connected respectively to the anodes of the third diodes of the third, first § and second channels, the cathodes of the fourth diodes of which are connected respectively ( I am with the cathodes of the sixth diodes of the first, second and third channels.

Description

co: o 1 The invention is intended for use in redundant sleep modes (automatic control systems, mainly in aviation automation systems. A three-channel major device is known that contains a signal source, a load resistor, two bias sources, and twelve O diodes in each channel. device is its relative complexity.Also known is a three-channel primary device containing a resistor in each channel, a signal source, a load resistor, two displacement sources and eight The diodes, the output of the signal source is connected through a resistor to the cathode of the first and anode of the second diode, the anode of the first and the cathode of the second diode are connected respectively to the anode of the third and cathode of the fourth diode and respectively to the plus and minus outputs of the first and offset point, the cathode of the third and anode Fourth diodes are connected to the cathode of the fifth and anode of the diode and through a load resistor to a common bus which is connected to the input of the signal source, the anode of the fifth and cathode of the sixth diode are connected respectively to the anode of seven the cathode of the eighth diode and, respectively, with the positive and negative outputs of the second bias source, the cathode of the seventh diode is connected to the anode of the eighth diode, the anodes of the eighth diodes of the first, second and third channels are connected respectively to the anodes of the fourth diodes of the second, third, and first channels, respectively, A disadvantage of the known devices is its relative complexity. The purpose of the invention is to simplify the device. To achieve this goal in a track-channel majority device containing a resistor, a signal source, a load resistor, a bias source and six diodes in each channel, the output of the signal source is connected to the cathode of the first and anode of the second diode through the resistor, and the cathode of the second diode are connected respectively, with the third anode and fourth cathode diodes, and with the positive and negative outputs of the source 8J bias, the third cathode and the anode of the fourth / i, H (j; io (oh / shneny with the fifth cathode and the anode of the sixth diode, respectively) in and through the common bus load resistor, which is connected to the input of the signal source, the anode of the fifth diodes of the first, second and third channels are connected respectively with the anodes of the third diodes of the third, first and second channels, the cathodes of the fourth diodes of which are connected to the sixth diodes of the first diodes :, th, second and third channels. The drawing shows a block diagram of a three-channel major unit (TMU). The MGU contains 1.1-1.3 signal sources, outputs 2.1-2.3 respectively 1.1-1.3 signal sources, diodes 3.1-8.1,3.2-8.2 and 3.3-8.3, resistors 9.1–9.3, bias sources 10.1–10.3, outputs 11.1–11.3, load resistors 12.1–12.3, and common bus 13. Outputs 2.1–2.3 of sources 1.1–1.3 are connected via resistors 9.1–9.3, respectively, to the cathodes of the first diodes 3.1–3.3 and c the anodes of the second diodes 4.1-4.3, the anodes of the first diodes 3.13, 3 are connected respectively to the anodes of the third diodes 5.1-5.3 and to the positive outputs of bias sources 10.1-10.3, the negative outputs of which are connected respectively to the cathodes of the second diodes 6.1-4.3 6.3, the anodes of which are connected respectively to the cathodes of the third diodes 5.1- 5.3, outputs 11.1-11.3, cathodes of fifth diodes 7.3, 7, 1 and 7.2, anodes of sixth diodes 8.3, 8.1 and 8.2 and load resistors 12.1-12.3 with common bus 13, which is connected to the inputs of sources 1.1-1.3 of signal, fifth anodes diodes 7.3, 7.1 and 7.2 are connected respectively to the anodes of the third diodes 5.3, 5.1 and 3.2, the cathodes of the fourth diodes 6.16 .3 are connected respectively to the cathodes of the sixth diodes 8.1-8.3 As a source of bias in systems with redundant devices that have a level, maximum output signals comparable to or greater than the supply voltage level of the amplifier Converter devices connected as a load of the TMU can be used as a current generator galvanically separated from the inputs and outputs.

LL systems with redundant devices that have a maximum output signal level that is lower than the supply voltage level of the secondary DC power sources (with a midpoint) of about 3V in both fields can be used as a bias source. Stable bias current sources connected between the respective poles of the diode links and the channel secondary power sources by a constant voltage (with a midpoint).

For systems with redundant devices that have a maximum output level of about 30% of the secondary supply voltage levels (midpoint), unipolar unbalanced bias current sources formed by ballast resistors connected in series can be used as bias sources. in the corresponding circuits between the poles of the diode links and the channel secondary sources of DC power supply (with a midpoint).

Resistors 9.1-9.3 are used to average the output signals with a natural error for real systems (within the calculated limits when the given error value is not considered to be a system failure) over the input signals.

The device works as follows.

In the absence of folding situations, all TMU diodes are in a conducting state, which ensures the transmission of reliable levels of input signals to all three device outputs, and the potentials of outputs 2.1–2.3 of sources 1.1–1.3 and outputs 11.1–11.3 are equal to each other. .

In the case of a tilting situation, for example, the potential at output 2.1 above the potentials at outputs 2.2 and 2.3, diodes 3.1 and 6.1 fO close and the circuit of the current generator included in the bias source 10.1 loads the current generators included in its composition

10.2 and 10.3, and since all the diodes

J5 3.2–8.2 and 3.3–8.3 keep conductive states, then equipotentiality of outputs 2.2, 2.3, 11.1, 11.2 and 11.3 is preserved

In the case when the negative positive signal falls on one of the TMU outputs, for example, on output 11.1, then on the other two outputs 11.2 and

11.3 reliable negative signal levels are maintained, since

5, the current of source 10.1 is closed through diodes 6.1 and 3.1, source 1.1, the common bus and the source of fault voltage, and the current of source 10.3 is closed through diodes 8.3 and 3.3,

source 1.3 and source of failure voltage.

At outputs 11.2 and 11.3, reliable levels are ensured due to the fact that all diodes 3.2-8.2 are in the conducting state.

In case of failure, for example, of the source 10.3 bias, at the outputs 11.1-11.3 there are reliable levels, since diodes 3.1-8.1 and 3.2-8.2 are open,

Thus, the introduction of the proposed connections into the device allows reducing one source of bias and two diodes per channel, which favorably distinguishes the proposed device from the known one.

Claims (1)

A THREE-CHANNEL MAJORITY DEVICE containing in each channel a resistor, a signal source, a load resistor, a bias source and six diodes, a signal source output connected through a resistor to the cathode of the first and the anode of the second diode, the anode of the first and the cathode of the second diode are connected respectively to the anode of the third and the cathode of the fourth diode, respectively, with the plus and minus outputs of the bias source, the cathode of the third and the anode of the fourth diode are connected to the cathode of the fifth and the anode of the sixth diode and through a load resistor with a common another, which is connected to the input of the signal source, characterized in that, for simplicity, the anodes of the fifth diodes of the first, second and third channels are connected respectively to the anodes of the third diodes of the third, first and second channels, the cathodes of the fourth diodes of which are connected respectively to the cathodes of the sixth diodes first, second and third channels.