CS203379B1 - Connection for measuring the jump length - Google Patents

Description

The invention relates to a circuit for measuring the length of a jump, for example skiers of ski jumpers on ski bridges.

The hitherto known arrangements for measuring the jump length of skiers are based on the principle of photoelectric sensing, laser sensing or induction.

The disadvantage of existing wiring in photoelectric sensing is mainly the high laboriousness of installing the photocells and maintaining their operability throughout the measurement. The laser solution is a very demanding and costly system for determining the length of a jump with the help of computer technology, which solves the intersection of the skier's ski jump curve with the jump-off curve. in that each loop has a separate evaluation circuit, thereby increasing the likelihood of failure of the entire device and costly.

These drawbacks are eliminated by the wiring of piro jump measurement for example skiers with an inductive sensor. It is based on the fact that the inductive transducer formed by a single insulated conductor is mounted on the landing area and at least some of it is alternately across the impact path of the skier, on whose ski a permanent magnet is mounted. The output of the inductive sensor is connected to the input of the evaluation circuit, the output of which is connected to the first input of the first gate, the second input of which is connected to the output of the second gate. The output of the first gate is coupled to the first input of the return counter, which is output to the input of the decoder, the output of which is connected to the first memory input and its output is connected to the display unit.

A second output of the control unit is connected to the second input of the counter. Its second output is connected to the second memory input and the third output of the control unit is connected to the first input of the second gate and the second input of the second gate is connected to the preset output.

The advantages of the circuitry according to the invention are that only one evaluation circuit is needed to evaluate the length of the jump of, for example, a ski jumper, since a single inductive sensor with one output is used, which makes the circuit considerably simpler, cheaper and more resistant.

203379 '2 faults. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram for measuring the length of a ski jump, e.g., skiers of ski jumpers, and FIG. 2 shows an example of the solution and the location of an inductive sensor on the ski jump landing area. . ,

The connection for measuring the length of the jump, for example skiers of ski jumpers on ski bridges, is such that an inductive sensor 11, which is formed by a single insulated conductor placed on the landing area D, for example a ski bridge, count. . intersect the path of the impact skiers diver with a fixed permanent magnet 10 on the ski, its output connected to the input of an evaluation circuit 12 whose output is connected to the first-vetu- PEM ¹ H1 first gate, whose second input is connected to the output H2 of the second gate, wherein the output of the first gate H1 is connected to the first input of the return counter 14, which is connected to the input of the decoder 15 whose output is connected to the first memory input 16 and its output is connected to the display unit 18. To the second input of the return counter 14, the first output of the control unit 11 is connected, the second output of which is connected to the second memory input 16 and the third output of the control unit 17 is connected to the first input of the second gate H2 and the second input of the second gate H2 is. linked to preset 13 output,

The device according to the invention operates in such a way that, for example, a ski jumper has a miniature permanent magnet 10 mounted on his ski, which induces an electromotive force therein at a certain distance from the inductive sensor 11, which is further evaluated by the evaluation circuit 12. It is apparent that at the output of the inductive sensor 11 and hence the evaluation circuit 12, a number of pulses equal to the number of parts of the conductor V traveled by the skier is reached by the jumper after his impact on the landing area. Said pulses from the evaluation circuit 12 are applied to the first input of the first gate H1, whose operating state is dependent on the presence of a signal on its second input, which is connected to the output of the second gate H2. The circuit 12 is connected to a return counter 14 which, in its initial state, is set to the maximum possible number of parts of the conductor V of the inductive sensor 11 traveled by the ski jumper. By the arrival of the scanned pulses, the state of the return counter 14 gradually decreases until the skier jumper passes through the last part of the wire V of the inductive sensor 11. The signal from the return counter 14 is then inputted to the decoder 15. The initial state of the counter 14 is set via its second input, which is coupled to the first output of the control unit 17, which interfaces both at the end of the measurement, and its second output, which is coupled to the a second memory input 16 for storing the measured value. Through preset 13 'are able to choose the base-T and R-phase, or repetitive measurement mode, so that the code 13 connected to a second input ^dru-: H2 Heho gate whose first input is controlled at repetičním metering mode from the third outlet <Control Unit 1 7. The second gate H2, by its output, then controls the operation of the first gate H1 and thus the entire measurement mode.

The circuit according to the invention can also be used for downhill skiers and on bridges covered with both snow and plastic. · ’. * ·

Claims (2)

object of the invention Circuit for measuring the length of a jump, for example skiers with an inductive sensor, characterized in that the inductive sensor (11) formed by a single insulated conductor (V) is mounted on the landing area (B) and at least some of it are alternately across the skier's impact path. the ski of which is fixed by a permanent magnet (10), the output of the inductive sensor (11) being connected to the input of the evaluation circuit (12), the output of which is connected to the first input of the first gate (H1) (H2), wherein the output of the first gate (H1) is coupled to the first input of the return counter (14), its output being connected to the input of the decoder (15), the output of which is connected to the first memory input (16) and its output is connected to a display unit (18), the second output of the counter (14) being connected to the first output of the control unit (17), the second output of which is connected to the d the second input of the second gate (H2) and the second input of the second gate (H2) are connected to the preset output (13). 2 sheets of drawings