CS242434B1 - Connection of two-stage impulse corrector - Google Patents

Abstract

The solution concerns a corrector of any pulse sequence from the lowest frequency to the frequency of the order of kHz, used wherever it is necessary to omit some pulses, for example, measuring the speed of a driving vehicle depending on the wheel diameter, in such a way that the coarse correction stage (22) and fine correction stage (35, 40) are arranged one after the other and in the program field (17, 30) it is possible to program which pulse in the sequence will be blocked (for example, every second or every fifth, etc., up to, for example, every 256th). This means that the series of pulses supplied to the internal terminal (02) will have all programmed pulses omitted at the output terminal (03). Repeated blocking of the programmed pulse sequence is ensured by a zeroing circuit consisting of gates (11, 12, 13) and an RC element (27, 29) for the fine corrector (35, 40).

Description

The invention relates to a two-stage pulse corrector for electronic correction of information generated by a speed sensor.

Existing track measuring and traction systems, which use pulse information from the speed sensor, convert the pulse information to an analog value before correcting the analog value, whose accuracy and stability is strongly dependent on adjusting elements, for example · potentiometers or a special foam divider must be used, which allows for example to program very fine analogue speed or distance data in the BCD code · Since the pulse distance data can be processed more easily and accurately than the analogue data in a practical solution, the information is corrected in relation to the real wheel diameter at the input pulse portion of such devices. There are also known solutions which use a number of replaceable gear discs for speed sensors and fine correction by suppressing some impulses (max. 2%) ·

The disadvantage of these solutions is that they require user intervention in the rotary encoder (disc replacement) in the event of a larger reduction in the diameter of the traction vehicle wheels by grinding, with greater maintenance of the vehicle.

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The above mentioned disadvantages are eliminated by the connection of the two-stage pulse corrector according to the invention, which consists of the negated product gates, BOD counters and diode program field. 6 to 50% of the total pulse count and a fine concealer, which is in series with the coarse concealer, which allows fine selection of pulse suppression in degrees from the lowest value of 0.25% of the total count. The principle of the invention is that the positive input terminal is connected via a series resistor to both inputs of the first product gate and simultaneously to the programming field of the first counter. The output of the first product gate is connected to the second input of the second product gate and its first input is connected to the input terminal of the pulse signal and simultaneously to the pulse input of the first four-row counter and to the first input of the third product gate.

The output of the second product gate is connected to the second input of the third product gate and simultaneously as the input of the second correction term to the input of the fifth product gate and the input of the sixth product gate and further to the pulse input of the second four-row counter. The output of the third product gate is connected through a reset circuit capacitor and in series with a resistor connected to an electrical zero, in parallel to the resistor the first protective diode is connected with its anode to electrical zero and a common point between the reset circuit capacitor and the resistor . The outputs of each decade are connected via cathodes and anodes of the programming diodes to the outputs of the program field, while the output of the program field is connected to an electrical zero. The input terminal is also connected via a series resistor to both inputs of the fourth product gate and simultaneously to all input terminals of the program field. The output of the fourth product gate is connected to the second input of the fifth product gate and its output is connected

242 434 with the second input of the sixth product gate and at the same time to the output terminal of the corrected pulse signal · The output of the sixth product gate is connected to a series capacitor with zero resistor to a common zero between the capacitor and the reset resistor is connected to the reset input of the second four-stroke counter and simultaneously to the reset input of the third four-stroke counter. The outputs of each decade are connected via the cathodes and anodes of the programming diodes to the outputs of the programming field. The output of the last decade of the second four-row counter is connected to the pulse input of the third four-row counter and the output of the program field is connected to the electrical zero. The outputs of each decade of the third four-row counter are connected via the cathodes and anodes of the programming diodes to the outputs of the programming field.

The assembled corrector allows for the selection of a considerable number of combinations, and thus virtually arbitrary input pulse suppression, and virtually allows for the entire range of wheel diameters used from 750 mm to 1360 mm previously used in traction vehicles with more than sufficient accuracy to adapt speedometer circuits to real diameter of used vehicle wheel. If higher correction accuracy is required, an additional coarse corrector may be included in the string so that the string consists of three concatenators in series, ie coarse + coarse + fine. The optimal calculation of the correction, ie the determination of the program table for individual wheel diameters and their possible deviations with respect to the observance of the maximum permissible error using the minimum number of program couplings, is not straightforward, since the final solution must also meet very high operational reliability requirements. The optimum calculation with this goal was performed on a self-realization computer and the procedure was followed so that in the suppression of some of a number of impulses there would be no larger gaps that could complicate further processing of information, especially when converting to an analog clock.

242 434 note at low vehicle speeds of less than 2 km / h. The correction performed in this way allowed the user to electronically correct the real wheel diameter of the traction vehicle for a wheel diameter range of 750 mm to 1360 mm in 5 mm increments with an accuracy of + 0.2 to 0.35% ·

An example of a connection according to the invention is shown on the neck.

Positive input terminal 01 is connected via a 10 x resistor and both inputs 111 and 112 of the first product gate 11 and simultaneously to the programming field 17 of the first counter 22. The output 113 of the first product gate 11 is connected to the second input 122 of the second product gate 12 and its the first input 121 is connected to the input terminal 02 of the pulse signal and simultaneously to the pulse input 221 of the first four-row counter 22 and to the first input 131 of the third product gate 13. input of the second correction term to input 251 of the fifth product gate 25 ' input 261 of the sixth product gate 26 and further to pulse input 351 of the second four-row counter 35 ' output 133 of the third product gate 13 ' connected through a neutral capacitor 14 and resistor connected in series 16 na elektr The first protective diode 15 is connected in parallel to the resistor 16 by its anode to the electrical zero and a common point between the neutral capacitor 14 and the resistor 16 is connected to the reset input 222 of the first counter 22. The outputs of the decades 223 * 224, 225 and 226 are connected via cathodes and anodes of programming diodes 18, 19, 20 and 21 to outputs 172, 173, 174 and 175 of programming field 17, while output 171 of programming field 17 is connected to electrical zero. · Output 243 of the fourth product gate 24 is connected to the second input 252 of the fifth product gate 25 and its output is connected to the second input 262 of the sixth product gate 26 and simultaneously to the output terminal 03 of the corrected pulse signal. The output 263 of the sixth product gate 26 is connected to a series capacitor 27 e with a resistor 29

242 434 to zero, the second protective diode 28 being connected in parallel to the reset resistor 29 with its anode to the electrical zero, while the common point between the capacitor 27 and the reset resistor 29 is connected to the reset input 352 of the second four-row counter 35 reset inputs 402 of the third four-row counter 40. Outputs of each decade 353, 354, 355, and 356 are coupled via cathodes and anodes of the programming diodes 31 to 33 with outputs 301 to 304 of the programming field 30. the input 401 of the third four-row counter 40 and the output 305 of the program field 30 are connected to an electrical zero. The outputs 403 to 406 of each decade of the third four-row counter 40 are connected via cathodes and anodes of the programming diodes 36 to 39 to the outputs 306 to 309 of the program pole 30 »

The connection of the coarse and fine correctors is the same, it differs by the number of digital decades used, which gives the range of the program field. For this connection it is necessary to observe the principle, if the requirement to omit eg the nth pulse is programmed bypassing / n - 1 / th pulse. For example, if a correction of 20% is required, ie every fifth pulse, it is necessary to program every fourth pulse. A counter that has a state change in the fourth pulse state in the program changes this state at the falling edge of the fourth pulse, at which point the corrector output is blocked so that the fifth pulse does not pass until after the pulse edge. a short pulse that resets the counter and repeats the process. A positive voltage (logic circuit supply voltage) is applied to the input terminal Ol, which feeds the coarse corrector 17 and fine corrector 30 program fields through resistors 10 and 23. »From the program field, this voltage is fed via diodes 18 to 21 to the coefficient counter 22 and via diodes 31-34 and 36-39 to the fine corrector counter 35 and 40 to output their respective decades in binary code (8, 4, 2, 1). If we start from the idle state when the counter * 22 is reset, then we have to

242 434

- β its outputs 223 »224» 225 and 226 with diodes 18, 19 »20 and 21 connected to zero voltage no matter which * of these decades are programmed with the exception of program jumper 17 connected to electrical zero, which means permanent coarse rejection that is, the concealer transmits all pulses, since at the inputs 111 and 112 of the negated product gate 11 is permanently logic 0, and thus at its output 113 is permanently logic 1, which means that it is also at the input 122 of the negated product gate 12 permanently logic 1. and the pulses applied to the gate input 12 from the input terminal 02 pass to the output 123, which is also the output of the coarse corrector. · Another condition occurs when an already modified example is programmed, ie · skipping 20% of the pulses · every fifth pulse is omitted, the fourth pulse is programmed, ie · the clutch is plugged in No · 174, which brings voltage logic 1 through diode 20 to the third Output 225 of counter 22. Upon completion of the fourth pulse, logic 1 appears at output 225, thereby also changing logic 0 at gate inputs 111 and 112, and logic 1, and at output 113 logical O, and hence 122 of gate 12 will be logic 0, which means that logic 1 will remain at output 123, even if the next fifth pulse arrives at input 121 immediately, which does not pass to the corrector output. one or the other of inputs 131 and 132 is still logic 0, and thus at its output 133 permanently logic 1, capacitor 14 charged to logic 1, but at the cathode of diode 15 and the resistor 16 connected in parallel, it was permanently zero; at zero, then at the time of the fifth pulse, the gate input 13 is logic 1 and the input 131 is also logic. then the fifth impulse ends (at the falling edge). Logic 1 remains at input 132 and logic 0 is input at input 131, which also means changing the state of pu 133 2 logic 0 to logic lfa, thereby providing a reset pulse to resistor 16, and hence to reset, via capacitor 14.

242 434 the input 222 of the counter 22 is reset and the process is repeated. The same process is carried out in the fine concealer. The only difference is that the fine concealer allows you to program any number from 2θ to 2θ, ie it can skip every second to 256th pulse. By programming clutch 305, this stage is permanently disabled and all input pulses coming from the coarse corrector to gate input 251 / will also appear at its output 253 and at the output terminal of the entire corrector 03 *

The difference of the fine corrector circuit versus the coarse corrector is that the last decade 356 of the counter 35 is connected to the input 401 of the counter stage 40 and the reset circuit is connected simultaneously to the reset inputs 352 and 402 of both counters.

Claims (1)

SUBJECT OF THE INVENTION 242 434 Connection of a two-stage pulse corrector, characterized in that the positive input terminal (01) of the supply voltage is connected via a series resistor (10) to both inputs (111, 112) of the first product gate (11) and simultaneously to the programming field (17) of the first counter (22), while the output (113) of the first product gate (11) is connected to the second input (122) of the second product gate (12) and its first input (122) is connected to the input terminal (02) of the pulse signal and simultaneously the input (221) of the first four-row counter (22) and further to the first input (131) of the third product gate (13) and the output (f23) of the second product gate (12) is connected to the second input (132) of the third product gate (13); simultaneously as input of the second correction term to input (251) of the fifth product gate (25) and input (261) of the sixth product gate (26) and further to the pulse input (351) of the second four-row counter (35) »whereas the output (133) of the third product gate (13) is connected to a neutral electrode via a reset circuit capacitor (14) and a resistor (16) connected in series with the first protective diode connected in parallel to the resistor (16) (15) by its anode to electrical zero and a common point between the reset circuit capacitor (14) and the resistor (16) is connected to the reset input (222) of the first counter (22), while the outputs of each decade (223, 224, 225 »226) are connected through cathodes and anodes of programming diodes (18, 19, 20, -21) to the outputs of the program field (172, 173, 174, 175) »whereas the output (171) of the program field (17) is connected to electrical zero and the input terminal (01) is connected via a series resistor (23) to both inputs (241, 242) of the fourth product gate (24) and simultaneously to all input terminals of the program field (30), while the output (243) of the fourth product gate (24) is connected to the second input (252) of the fifth product gate (25); its output (253) is connected to the second input (262j of the sixth product gate (26) and simultaneously to the output terminal (03) of the corrected pulse signal, while the output (263) of the sixth product gate (26) is connected - 9 242 434 for a series capacitor (27) with a resistor (29) to electrical zero, with a second protective diode (28) connected in parallel to the resistor (29) with its anode to electrical zero, while a common point between the capacitor (27) and a reset resistor (29) is connected to the reset input (352) of the second four-row counter (35) and simultaneously to the reset input (402) of the third four-row counter (40), while the outputs of each decade (353 »354» 355 »356) ), the cathodes and anodes of the programming diodes (31, 32, 33, 34) are connected to the outputs (301, 302, 303, 304) of the program field (30), the output of the last decade (356) of the second four-row counter (35 * 1) simultaneously connected to the pulse input (401) of the third counter (40), and the output (305) of the program field (30) is connected directly to electrical zero, while the outputs (403, 404, 405, 406) the counters (40) are connected via cathodes and anodes of programming diodes (36, 37, 38, 39) to the outputs (306, 307, 308, 309) of the program field (30);