RU2488419C1 - Method to determine length of jump during track and field horizontal jump events - Google Patents

Abstract

FIELD: sports.

SUBSTANCE: invention relates to equipment of sports sites for broad jumps and triple jumps and may be used both in sports competitions and in the training process. The method to determine jump length, characterised by usage of a jumping board with a mark and a pit with sand as a zone of sportsman landing. Besides, the pit with sand is covered with soft material in the form of a mat, on the surface of which pressure sensors are applied with a pitch of not more than 1 cm², and their coordinates are entered into the memory of the measurement system, and the jump length is determined by means of the difference of the distance from the actuated pressure sensor nearest to the jumping board to the mark on the jumping board.

EFFECT: increased convenience and safety during sportsman landing, provision of the possibility to measure jump length without use of complicated equipment.

5 cl, 2 dwg

Description

The invention relates to the equipment of sports grounds for long jumps and triple jumps and can be used both in sports and for training purposes.

Long jumps (see http://ru.wikipedia.org/wiki/Length_Length) are carried out in the sector for horizontal jumps according to the general rules established for this kind of technical species. When performing a jump, athletes in the first stage take a run on the track, then push off with one foot from a special bar and jump into a sand pit. The jump range is calculated as the distance from the special mark on the push bar to the beginning of the hole from landing in the sand.

Currently, horizontal jumps in athletics are carried out in jumping pits filled with sand (river, sea, quartz, taken from quarries, etc.). In practice, sand in jump pits in stadiums is rarely replaced, foreign objects (leaves, grass, branches, etc.) get into it and under certain conditions (high humidity, hot period of time) microflora is brought in.

In addition, upon landing the athlete who has completed the jump, the sand scatters in all directions, falling not only on clothing, but often in the eyes of the referee staff serving this type of athletics competition, which can lead to temporary loss of vision.

It should also be noted that sand is a very “hard” traumatic material: often during competitions and in training, athletes get injuries associated with sprain and displacement of joints in the lumbar and knee areas.

Also, measurements of the athlete's landing site are made manually following the trail of a hole in the sand. In the process of landing, the true track is “lubricated” by ejecting masses of sand in the zone of the landing hole (the so-called crater formation is similar to the effect of a meteorite falling). Measurements are made on the caldera of the hole trace, although the true boundary of the trace is always further. And the stronger the impact on the ground, the greater the ejection of soil and the greater the caldera and measurement error, which reduces the athlete’s testimony downward.

It is possible to reduce errors in measuring long jumps by installing measuring equipment that records the length of the jumps.

The prior art device for determining the length of the jump (SU 1591233), containing the first group of N radiation sources and N radiation receivers installed horizontally at equal intervals between each, and each radiation source is optically connected to its corresponding radiation receiver, the outputs of the radiation receivers through the first group of inputs of the processing unit is connected to an indicator, characterized in that, in order to improve usability, the first group of receivers and radiation sources is installed in the push zone As a sector for jumping, an additional group of radiation sources and receivers is installed in the device, installed in the landing zone of the jumping sector, the outputs of additional radiation receivers connected to the second group of inputs of the information processing unit, and the information processing unit containing a threshold block, a first signal selector, the first calculator, second signal selector, second calculator, register, adder, read permission block, converter, first and second delay circuits, logic block, block element in AND, a block of OR elements, wherein the outputs of the first signal selector are connected to the inputs of the first calculator, the outputs of which are connected to the first group of inputs of the adder, and the outputs of the second group of radiation receivers are connected to the inputs of the second signal selector, the outputs of which are connected to the inputs of the second calculator, the group of inputs of which the register is connected, and the outputs of the calculator are connected to the second group of inputs of the adder, the outputs of which are connected to the read permission block, the outputs connected to the second ind a kator, the outputs of which are connected to the first group of inputs of the block of OR elements connected to the first indicator, the second output of the first signal selector connected to the first input of the logic block, and the third output of the first signal selector through the first delay circuit connected to the second input of the logical block, the second output of the second selector is connected to the third input of the logic unit, and the third output of the second selector is connected through the second delay circuit to the fourth input of the logical unit, the first the second, third and fourth inputs of the logic block are connected respectively to the second, third, fourth and fifth inputs of the read permission block, and the output of the logic block is connected to the input of the AND block, the outputs connected to the second group of inputs of the block of OR elements.

Significant disadvantages of this device are the low reliability due to the large number of contacts, and low accuracy. At the same time, the device does not exclude sand in the athlete’s landing zone with all its negative properties.

A device (SU1155278) for recording jump performance parameters is known, comprising a series of consecutively placed strips with contacts mounted beneath them and a recording device including a calculator based on digital logic elements and indicators.

Significant disadvantages of this device are the low reliability of operation, due to the large number of contacts, and low measurement accuracy due to the inability to place strips of large length (for example, 4 m long when jumping in height) with a sufficiently small step. At the same time, the device does not exclude sand in the athlete’s landing zone with all its negative properties.

A device is known (RU 2106171) for determining the size of an athlete’s jump, comprising a block of radiation sources with radiation sources installed with an equal pitch, a block of radiation receivers with radiation receivers installed with the same step in terms of the number of radiation sources, with each radiation receiver located opposite the corresponding radiation source and makes up an optocoupler with it, characterized in that a block of threshold elements and a calculator, connected to the output is connected to the indicator, the clock generator, the optocoupler address generation unit, the radiation source control unit and the signal switch, the clock generator is connected to the optocoupler address generation unit, the outputs of which are connected to the radiation source control unit, the control inputs the signal switch and the second inputs of the calculator, the radiation sources are connected to the outputs of the control unit of the radiation sources, the inputs of the signal switch are connected to the outputs b eye threshold elements, and the output - to the third input of the calculator.

The disadvantage of this solution is the technical complexity of the installation of this equipment, low accuracy of measurements. At the same time, the device does not exclude sand in the athlete’s landing zone with all its negative properties.

A device for estimating the value of jumps (RU82127U), containing a block of radiation sources installed with equal pitch, a block of radiation receivers according to the number of radiation sources installed with the same step and oriented against the same radiation sources, so that the same radiation sources and receivers constitute optocouplers, as well as an information processing unit connected to the block of radiation receivers, in which the inputs of the threshold elements are connected to the outputs of the same sources of radiation, and an indicator that differs That has been entered with embedded base layer for leveling and hinges with clamps at the ends for the connection blocks radiation sources and receivers, as well as in the information processing unit incorporated filter discrete information unit variance estimation parameters and the second block indication.

The solution is chosen for the prototype.

The disadvantage of this solution is the technical complexity of the installation of this equipment, low accuracy of measurements. At the same time, the device does not exclude sand in the athlete’s landing zone with all its negative properties.

The aim of the invention is the replacement of sand with softer material, eliminating the negative properties of sand and providing the ability to control the traces of the landing of an athlete without the use of sophisticated equipment.

The technical result of the invention is to increase the convenience and safety when landing an athlete, providing the ability to measure the length of the jump without the use of sophisticated equipment.

The specified technical result is achieved due to the fact that the method of determining the length of the jump, characterized by the use of a push bar with a mark and a sand pit as an athlete’s landing zone, is characterized in that the sand pit is covered with a soft material in the form of a mat, the surface of which does not step by step more than 1 cm ² is applied to the pressure sensor, the coordinates of which are entered into the memory of the measuring system and the length of the jump distance is determined by a difference from the neighbor to the bar repulsion actuated pressure sensor up to the mark on the bar repulsion. In addition, the ends of the mat are pulled on opposite sides, forming a constant tension of the mat so that it retains its spatial position.

Pressure sensors are installed in parallel lines along the length and width of the mat. Along the length of the mat, after a given step (corresponding to the placement interval of the sensors), the ends of the active zone circuits passing along the width of the fault wires are output, each of which connects all sensors located at the same distance along the mat length and, if one of the pressure sensors is triggered, it activates the fault wire , which forms the active zone, moreover, in the measurement system, for the calculation of the length of the jump, readings are taken only from the closest active zones that have worked. When the athlete steps on the mark (start line of counting the length of the jump), the pressure sensor is triggered and a zero is displayed on the information board, which means that the attempt is not counted.

The invention is illustrated by drawings.

In FIG. 1 shows an example implementation of the invention, where 1 is a repellent bar, 2 is a sand pit, 3 is a soft mat-type material with pressure sensors applied over it, 4 is an information board with a measurement system, 5 is contact wire, 6 is a mat tension cable.

In FIG. 2 shows the principle of operation of the mat sensors, where 7 is the athlete’s footprint, 8 are the triggered pressure sensors, 9 are the active zones, 10 are inactive sensors, 11 are the circuit wires of the active zone circuits.

The implementation of the invention.

The invention can be implemented as follows.

From the repulsion bar (1) with the mark and to the sand pit (2) as the athlete’s landing zone, the distance is always known for sure. Also, when installing soft material in the form of a mat (3), it is possible to precisely fix the distance D from the mat (3) to the repulsion bar (1) (see Fig. 1).

Pressure sensors are applied to the surface of the mat (3) with a step of no more than 1 cm ² , the coordinates of which are recorded in the memory of the measurement system, and the jump length is determined by the difference in distance from the closest pressure sensor (8) that is closest to the push rod (1) to the mark on the push bar.

To keep the mat (3) in a constant position (to prevent it from shifting) it is preferable that the ends of the mat are pulled by cables (6) on opposite sides to the pit (2), forming a constant mat tension.

When the athlete lands on the mat (3), he leaves traces (7), according to the closest of which, according to the rules of the competition, the results of the jump length are counted.

The principle of taking readings from the mat (3) about the length of the jump can be implemented using triggered pressure sensors (8). Pressure sensors (8) can be installed in parallel lines along the length and width of the mat (3). Along the length of the mat through a predetermined step (corresponding to the placement interval of the sensors), but not more than 1 cm, the circuit wires (11) of the active zone circuits (9) are output, each of which connects all the sensors (8) located at the same distance along the length of the mat.

In the event that one of the pressure sensors (8) is triggered, it activates the fault wire (11), which forms the active zone (9).

The athlete’s footprint (7) on the mat (3) (see Fig. 2) forms several active zones (9). But the measurement system takes for calculation the readings of only the closest active zones (9), the distance from the mark on the bar (1) to which will be considered the length of the jump according to the rules of the competition.

Each of the active zones (9) is listed in the coordinate system of the measurement system (4), which can be set inside the information panel that automatically generates data about the jump. The measurement system can be a microcontroller or a computer in which the program for calculating the length of the jump and data on the coordinates of all active zones are flashed or recorded.

Jump length X is calculated using a simple formula:

X = D + d, where d is the distance from the beginning of the mat (3) to the nearest activated core (9). The value of D entered into the measurement system as a correction.

The origin of the length calculation coordinates is the proximal end of the mat (3) to the bar (1).

When preparing the measurement system (4) and mat (3) for work on measuring the length of jumps, in addition to laying and tensioning the mat, it is necessary to enter the distance D of the initial position of the mat (3) from the mark on the bar (1). This distance D is measured with great accuracy several times with a tape measure, after which its value as a correction value is entered into the measurement system. After that, the measurement system will give accurate readings along the length of the jumps of athletes.

Claims (5)

1. A method for determining the length of a jump, characterized by the use of a push bar with a mark and a sand pit as an athlete’s landing zone, characterized in that the sand pit is covered with a soft material in the form of a mat, on the surface of which pressure sensors are applied with a step of no more than 1 cm, the coordinates of which are recorded in the memory of the measurement system, and the length of the jump is determined by the difference in distance from the closest to the repulsion bar of the triggered pressure sensor to the mark on the repulsion bar. 2. The method according to claim 1, characterized in that the ends of the mat are pulled on opposite sides, forming a constant tension of the mat so that it retains its spatial position. 3. The method according to claim 1 or 2, characterized in that the pressure sensors are installed in parallel lines along the length and width of the mat. 4. The method according to claim 3, characterized in that along the length of the mat through a predetermined step (corresponding to the placement interval of the sensors), the ends of the active zone circuits passing along the width of the circuit fault wires are output, each of which connects all sensors located at the same distance along the mat length, and if one of the pressure sensors is triggered, it activates a fault wire, which forms the active zone, and in the measurement system, only the closest active zone that has worked is used to calculate the jump length. 5. The method according to claim 4, characterized in that when the athlete steps on the mark (start line of the jump length), the pressure sensor is triggered and a zero is displayed on the information board, which means that the attempt is not counted.

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