CS239114B1 - Frequency-to-analog converter connection - Google Patents

Abstract

Connection of a frequency-to-analog converter for processing signals from photoelectric pulse sensors. The input signal is passed through two negative product gates to one ρδΐ capacitor, the other pole of which is connected to the base of the transistor. After the pulse ends, the transistor opens and the opening time is determined by the time constant of the capacitor and the excitation resistor. While the transistor is open, the voltage stabilizer sends pulses of a defined length and amplitude. These pulses are converted into a pulse through an operational amplifier connected as an active filter, the mean value of which is proportional to the pulse density at the input of the circuit. The invention will be used in frequency-to-analog converters for registration tachographs on public transport vehicles.

Description

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Connection of frequency converter

Connection of frequency converter for processing signals from photoelectric pulse sensors. The input signal is passed through two negative product gates to one ρδΐ of a capacitor whose other pole is connected to the base of the transistor. When the pulse is terminated, the transistor opens and the opening time is determined by the time constant of the capacitor and the drive resistor. When the transistor is open, the voltage stabilizer sends pulses of defined length and amplitude. These pulses, via an operational amplifier connected as an active filter, change into a paper whose mean value is proportional to the pulse density at the input input. The invention will be utilized in frequency analogue converters for registration tachographs on public transport vehicles.

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BACKGROUND OF THE INVENTION The invention relates to a frequency-analog converter for processing a frequency signal from a pulse speed sensor.

Known frequency-to-analog converters are designed as a monostable flip-flop with stabilized amplitude of the output pulses. The amplitude of the output pulses is stabilized either by a zener diode or by a more complex transistor or integrated circuit. The disadvantage of these circuits is that they do not guarantee zero voltage in the interval between two pulses. In addition, for circuits that use a transistor, this voltage is dependent on ambient temperature. For more accurate transducers, this thermal dependence is compensated by additional additional compensation circuits, which make the connections more expensive and more complicated. For some transmitters, the function is relatively easily disrupted by the intrusion of an undesired signal on their input, for example due to interfering pulse currents, which cause, for example, the switching of high-current contacts or thyristors. They usually do not meet the requirements for DC output voltage or DC output current, with minimal ripple to ensure accurate transmission with the shortest response.

These drawbacks are largely eliminated by the wiring of the frequency-to-analog converter according to the invention. The principle of the invention is that the input terminal of the circuit is connected to the first input of the first gate, the second input of which is connected to the output of the third gate. The output of the first gate is connected to both inputs of the second gate of which

The output of the capacitor is coupled to one pole of the capacitor. The other pole of the capacitor is coupled to one terminal of the excitation resistor and to the base of the transistor whose emitter is coupled to the zero potential. The transistor collector is connected to the voltage stabilizer control terminal and one operating resistor terminal, the other terminal of which is connected to both the third gate inputs and the diode anode. with a voltage stabilizer power terminal whose output terminal is connected to an operational amplifier input whose output is connected to the wiring output terminal.

The advantage of connecting the converter according to the invention is that it eliminates unwanted output voltage during the time between individual pulses from the monostable flip-flop. The connection is not dependent on the ambient temperature and therefore no thermal compensation is required. It prevents any interfering signals at the converter input from affecting the output signal for a time given by the time constant of the capacitor and the drive resistor. The wiring is made up of cheap and readily available components, which positively affects its cost.

An example of a frequency-analog converter according to the invention is shown in the block diagram of the attached drawing.

The main component and wiring blocks can be characterized as follows. All three gates 1, 2, 2 are the same two-input negated NAND product gates. Used to negate the logical product of the signals at their inputs. The voltage stabilizer 2 is formed from an integrated circuit, a capacitor, fixed resistors and one variable resistor. It serves to stabilize the supply voltage according to the signal on its control terminal 91

-3 239 114 feedback resistor and capacitor connected and works as an active filter · Serves to evaluate an analog voltage value that is proportional to the frequency of the input pulses · Connection is made as follows · Input terminal 01 of the connection is connected to the first input 11 of the first gate 1. the input 12 of the first gate 1 is connected to the output 33 of the third gate 2. The output 13 of the first gate 1 is connected to the two inputs 21, 22 of the second gate 2. The output 23 of the second gate 2 is connected to one pole. the transistor 8 is connected to zero potential. The collector of transistor 8 is connected to the control terminal 91 of the voltage stabilizer 2. and to one of the terminals of the working resistor. The second terminal of the working resistor 2 is connected to both inputs. of the third gate 2 and the anode of the diode 2 * The cathode of the diode 2 is connected to the second The second power supply terminal 03 is connected to the power terminal 92 of the voltage stabilizer 2. The output terminal 93 of the voltage stabilizer 2 is connected to the input 101 of the operational amplifier 10. The output 102 of the operational amplifier 10 is connected to the output terminal 04 of the wiring. The first power supply terminal 02 is connected to the positive pole of the first power supply voltage. The second supply terminal is connected to the positive terminal of the second supply voltage. The pulse digital signal is applied to the input terminal 01 of the wiring and from there to the first input 11 of the first gate 1. Assuming that the second input 12 of the first gate 1 has a log signal. 1, then after the arrival of the signal log. 1, at the first input 11 of the first gate 1, a signal log appears at the output 13 of the first gate 1. This signal log · 0 passes to both inputs 21 and 22 of the second gate 2. The second gate 2 negates the logical sum of the signals at its inputs 21 and 22, so at the output 23 of the second .tf.

239 114 of the gate 2 is a log · 1 signal. This voltage charges the capacitor 8 across the base and the emitter of transistor 8. This did not change the state of transistor 8 since it was energized by positive current from positive power terminal 02 terminating the input pulse on the wiring input terminal 01 when the log · 0 signal at the first input 11 of the first gate JL is outputting its log. 0 and the output 23 of the second gate 2 is a log · 0 signal. Transistor 8 is a negative voltage and the transistor 8 closes. The collector of transistor 8 is at the control voltage level of the control terminal £ 1 of the stabilizer resistance χ to both inputs 31 and 32 of the third gate 2 ^and at the same time the voltage across diode 2 is limited to the positive supply voltage level at the positive supply terminal 02 of the wiring. at the output 21 of the third gate 2, the signal log · 0 * This signal blocks the first gate 11 through the second input 11 and until the polarity of the capacitors 6 and the capacitors 8 are determined by the polarity reversal constant 6. At this time, the first input 01 of the wiring will receive a disturbing signal, for example when the contacts are closed, this disturbing signal will not affect the · When the time constant has elapsed and the capacitor 8 is reversed and the transistor 8 is switched on again and the wiring is restored to its original state · When the next pulse is received, this operation is repeated · and during this time there will also be an impulse at output 92 of stabilizer 2 · This output is precisely defined by length and amplitude · When transistor § turns on, output 93 of stabilizer χ is zero voltage ·

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The normalized pulses are applied to the input 101 of the operational amplifier 10. The operational amplifier 10, which operates as an active filter, has at its output 102 a non-ripple analogue signal whose value is proportional to the frequency of the input pulses.

The invention will be used for frequency-to-analog converters in the processing of pulses from four-wire sensors, especially for registration tachographs on public transport vehicles.

Claims (1)

SUBJECT OF THE INVENTION 239 114 A frequency-to-analog converter connection, characterized in that the input connection terminal (01) is connected to a first input (11) of the first gate (1), the second input (12) of which is connected to the output (33) of the third gate (3) and output (13) of the first gate (1) is connected to both inputs (21, 22) of the second gate (2), the output (23) of which is connected to one pole of capacitors (4), the other pole of which is connected to one terminal 6) and with the base of the transistor (8) whose eraitor is connected to zero potential The transistor (8) is connected to the control terminal (91) of the voltage stabilizer (9) and to one working resistor terminal (7) »the other terminal is connected to both the inputs (31, 32) of the third gate (3) and the anode of the diode (5), the cathode of which is connected to the second excitation resistor terminal (6) and the first power terminal (01) of the wiring, the second power terminal (03) a clamp (92) of a voltage stabilizer (9) of which the output terminal (93) is connected to an input (101) of the operational amplifier (10), the output of which (102) is connected to the output terminal (04) of the wiring.