RU2032272C1 - Radio receiver interference susceptibility tester - Google Patents

Abstract

FIELD: radio electronics. SUBSTANCE: device has three generators 1,4,7, three counters 2,5,9, two digital-to-analog converters 3,6, adder 8, two decoders 10,18, controlled attenuator 11, trigger unit 12, subtracter 13, storage unit 14, comparator 15, amplitude detector 16, comparison unit 17, two indicators 19,21, flip-flop 20, and radio receiver 22 under test. EFFECT: provision for testing radio receiver dynamic range by intermodulation of desired type. 1 dwg

Description

 The invention relates to radio engineering and can be used to control the dynamic range of a radio receiver for intermodulation of a given type.

 The drawing shows a structural electrical diagram of a device for monitoring the susceptibility of a radio receiver to interference.

 The device for monitoring the susceptibility of a radio receiver to noise includes a series-connected clock generator 1, a first pulse counter 2, a first digital-to-analog converter (DAC) 3 and a first controlled oscillator 4, connected in series with a second pulse counter 5, the input of which is connected to the overflow output of the first pulse counter 2, the second digital-to-analog converter (DAC) 6, the second controlled generator 7 and the adder 8, the second input of which is connected to the output of the first controlled generator 4, in series about connected the third counter 9 pulses, the input of which is connected to the overflow output of the second counter 5 pulses, the first decoder 10 and the controlled attenuator 11, the signal input of which is connected to the output of the adder 8, and the output is the input of the monitored radio 22, the launch unit 12, the output of which is connected with a blocking input of the clock generator 1, the calculator 13, the first and second inputs of which are connected respectively to the information outputs of the first and second counters 2 and 5 pulses, the memory unit 14, the information input to which is connected to the information output of the first pulse counter 2, a comparator 15, the output of which is connected to the gate input of the memory unit 14, an amplitude detector 16, the output of which is connected to the input of the comparator 15, and the input is the output of the monitored radio 22, the comparison unit 17, the first and second the inputs of which are connected to the outputs of respectively the calculator 13 and the memory unit 14, the second decoder 18 connected in series, the input of which is connected to the output of the memory unit 14, and the first indicator 19, trigger 20, information input One of which is connected to the output of the comparison unit 17, the gating input - with the output of the comparator 15, and the output - with the input of the start unit 12, the second indicator 21, the first and second inputs of which are connected to the outputs of the first decoder 10 and trigger 20, respectively.

 The clock generator 1 is made on digital microcircuits 561LA7.

 The first and second counters 2 and 5 pulses are made on microcircuits 561IE14 and 561LA7.

 The first and second digital-to-analog converters 3 and 6 are made on the K572PA1A and K140UD8 microcircuits.

 The first and second controlled generators 4 and 7 consist of a high-frequency generator with two transistors, made on the principle of compensating for losses in the circuit due to positive feedback, and a power amplifier with an output transformer for matching the output resistance of the power amplifier and the input resistance of the adder. A varicap is included in the oscillatory circuit of the high-frequency generator, with the help of which the generator is tuned in frequency.

 The adder 8 is made on resistors.

 The third counter 9 pulses made on digital microcircuits 561IE10.

 The first and second decoders 10 and 18 are made on digital microcircuits 561ID1 and 561ID5, respectively.

 The controlled attenuator 11 is a resistive matrix, and since the difference in attenuation between adjacent levels is the same, the matrix is made on the required number of resistors of two denominations. Level switching is performed using RES49 relays controlled by electronic keys on transistors of the KTS613B microassembly.

 Launch block 12 is made on 561LA7 digital microcircuits.

 The computer 13 is made on microcircuits 561IM3 and 561IM4.

 The memory unit 14 is made on chips 176RU2.

 The comparator 15 is made on an analog chip 140UD8.

 Amplitude detector 16 is a serial diode detector.

 Block 17 comparison is made on digital microcircuits 561IP2.

 The first indicator 19 is made on a seven-segment LCD.

 The trigger 20 is made on 561TM3 microcircuits.

 The second indicator 21 is a matrix of light-emitting diodes of the type AL307A with cross-switching, emitting light when a direct current is applied to the corresponding element.

 A device for monitoring the susceptibility of a radio receiver to interference works as follows.

The pulses from the output of the clock generator 1 are fed to the input of the first (reverse) counter 2 pulses (mod M ₁ ). A sequence of binary codes of numbers from 0 to M ₁ is formed on its information output:
M ₁ = Df / Δ F, where Df is the operating frequency range;
Δ F is the bandwidth of the radio.

These codes are converted by the first digital-to-analog converter 3 into a stepwise increasing voltage. When the number M _{1 is} reached, the overflow signal is generated at the overflow output of the first counter 2 pulses, which switches the addition function to the subtraction function. In this case, a decreasing sequence of numbers from M ₁ to 0 will be formed, with the help of which the first digital-to-analog converter 3 will form a stepwise decreasing voltage. When reaching 0, a loan signal is generated, which will change the subtraction function to the addition function and the process will be repeated. The triangular-shaped voltage thus obtained controls the scanning of the frequency f _{1 of the} first controlled oscillator 4 in the range Df.

The pulses of the change of functions from the overflow output of the first counter of 2 pulses are fed to the input of the second counter (reverse) of 5 pulses (mod M ₂ = M ₁ ), which together with the second digital-to-analog converter 6 will generate a triangular voltage that controls the scanning of the frequency f _{2 of the} second controlled generator 7 in the range Df.

 The power level of the first and second controlled generators 4 and 7 is the same, since there is no reason to set other ratios. Next, the signals are fed to the adder 8, the output of which the total signal is fed to the signal input of the controlled attenuator 11.

The pulses of the change of functions of the second counter of 5 pulses are fed to the input of the third counter of 9 pulses (mod M ₃ )
M ₃ = h, where h is the number of levels of the controlled attenuator 11.

The possible power range at the output of the controlled attenuator 11 is
DP (dB) = 10 log (P _bl / P _o ), where P _bl is the power of the blocking interference (specified by the relevant standards);
P _about - threshold sensitivity of the radio.

Number of Attenuation Levels
h = 1 + DP / Δ P, where Δ P (dB) is the required resolution of the change in the power of the probe signal.

 Thus, under the influence of the input pulses at the output of the third counter 9 pulses, binary codes of numbers from 0 to h sequentially appear, which are decoded by the first decoder 10, the output signal of which sequentially switches the controlled attenuator 11 to the corresponding attenuation levels.

 From the output of the controlled attenuator 11, a probing effect is applied to the input of the controlled radio 22, the responses of which from the output of its intermediate-frequency amplifier are supplied to an amplitude detector 16, from the output of which the response envelope is supplied to a comparator 15, designed to normalize the response amplitude to match the input levels of digital microcircuits .

Next, the pulses corresponding to the responses are fed to the gate input of the memory unit 14. The information input of the memory unit 14 receives binary codes of numbers N ₁ from the information output of the first counter 2 pulses, linearly related to the generation frequency of the first controlled oscillator 4. Since the increase in the power of the probing signal at the output of the controlled attenuator 11 begins with a value of P _o corresponding to the sensitivity threshold controlled radio receiver, then the first response at its output will correspond to the main reception channel, and the binary code of the number N ₁ = N _о present at this point in time at the output The first counter of 2 pulses will correspond to the tuning frequency of the radio.

 From the output of the memory unit 14, the fixed code goes to the second decoder 18, the output of which is connected to the first digital indicator 19. At the same time, the exact numerical value of the tuning frequency of the radio receiver will appear on it. Comparison of the obtained value with the approximate value determined on the scale of the radio receiver allows us to verify its reliability.

At the first and second inputs of the calculator 13 from the outputs of the first and second counters 2 and 5 pulses are binary codes of numbers N ₁ and N ₂ , the values of which are linearly related respectively to the frequencies f ₁ and f _{2 of the} output signals of the first and second controlled generators 4 and 7. The calculator 13 performs the arithmetic operation in binary codes according to the formula corresponding to a given type of intermodulation. For example, for 3rd order intermodulation in accordance with the formula
| 2f ₁ - f ₂ | = f _o ;
| 2N ₁ - N ₂ | = N _x .

The binary code of the number N _{x is} supplied to the first input of the comparison unit 17. At its second input, the binary code of the number N _{o is} received. At the output of the comparison unit 17, pulses with a logic level of “1” will appear at times when the condition N _x = N _o will be fulfilled. Thus, the moments of time of the possible appearance of a given type of intermodulation in the radio are recorded.

 The pulses from the output of the comparison unit 17 are sent to the information input of the trigger 20. At its gate input from the output of the comparator 15, the responses of the controlled radio receiver to the probing effect are received. With their simultaneous receipt, the trigger 20 switches to the second stable state and the logical level “1” will appear at its output.

 In this way, the responses that occur at the output of the monitored radio receiver during the measurement and the corresponding intermodulations of a given type are recorded.

 The logical level "1" from the output of the trigger 20 is supplied to the first input of the second indicator 21.

 The second indicator 21 is a matrix of h LEDs, the anodes of which are connected to the first input of the indicator. The second input of the indicator is the conclusions of the LED cathodes connected to the corresponding terminals of the first decoder 10. When switching the attenuation levels of the controlled attenuator 11, the corresponding LEDs are synchronously connected to the zero potential (the first decoder has inverse outputs). When the second logical level indicator “1” appears at the first input of the second indicator, the LED corresponding to the power level of the probing signal present at a given moment of time starts to glow, and thereby fixes the level of intermodulation of a given type in the radio receiver.

 After the appearance of the trigger level 20 logical "1" at the output, it also goes to the start block 12, the output of which will appear at the same time the blocking level of the clock generator. The control process will end. Thus, the measurement cycle is fully automated.

 At the next start, after pressing the button that is part of the start-up block 12, a level will appear at its output allowing the operation of the clock generator 1, and the measurement process will be repeated.

Claims (1)

 DEVICE FOR RADIO RECEIVER SENSITIVITY CONTROL, comprising a controllable attenuator, a controlled radio receiver and an amplitude detector, a first counter, two generators, an adder, a memory unit, a comparator, a trigger and a first indicator, characterized in that, in order to provide the possibility of controlling the dynamic range of the radio receiver by intermodulation of a given type, a start-up block and a clock are introduced in series, the output of which is connected to the input of the first counter, last interconnected second counter, the input of which is connected to the first output of the first counter, the third counter and the first decoder, the output of which is connected to one input of the controlled attenuator, two digital-to-analog converters, the input of the first digital-to-analog converter is connected to the output of the first counter, and the output is connected to the input of the first generator the output of which is connected to the first input of the adder, the second input of which is connected to the output of the second generator, the input of which is connected to the output of the second digital-analog a generator, the input of which is connected to the second output of the second counter, the output of the adder is connected to the second input of the controlled attenuator, a calculator is connected in series, one input of which is connected to the second output of the second counter, and the second input is connected to the second output of the first counter and combined with the first input of the memory unit , and a comparison unit, the output of which is connected to one input of the trigger, the second input of which is connected to the output of the comparator, which is connected to the second input of the memory unit, the output of which is connected respectively to the second input of the comparison unit and the input of the entered second decoder, the output of which is connected to the input of the first indicator, the second indicator, one input of which is connected to the output of the first decoder, and the second input is connected to the output of the trigger, which is also connected to the input of the trigger unit, the amplitude output the detector is connected to the input of the comparator.