SU876108A2 - Device for determining physical load - Google Patents

Description

The invention relates to medical technology and can be used for diagnostic and experimental purposes.

According to the main author. St. № 665 892 discloses a device comprising a unit ⁵ changes rhenium pulse frequency down counter, the comparison block generator repetition command time interval and serially connected adder de fr shi a torus circuit block _{(block 0} coincidence and stimuli, and the decoder input through sequentially connected comparison unit and a reversible counter are connected to one of the inputs of the adder, the other input of which is connected to the output of the pulse frequency measuring unit, and the output of the generator of the time interval for following the commands is connected to the input block matching schemes [1] ·

However, the known device does not obes- _χ ensures, ability to perform complex patient rhythm 'movements. This is due to heme, which the known device of the command gives out evenly (like a metronome), only changing their frequency. To perform the same exercise? having a complex rhythm of movements, uneven intervals between command signals are required, corresponding to the duration of muscle movements * in the complex holistic action of the patient.

It is known that the temporal characteristics of muscle movements include their duration, pace and rhythm. The rhythm of movements is a measure of the ratio of individual phases, a complex characteristic of movement, organizing its individual phases into a single integral action.

The ratio and sequence of these phases of the known device does not take into account. In addition, this device also does not take into account the presence of accentuated phases of movements in physical exercise, which is especially important when performing physical exercises with a complex rhythm, since without accenting, for example, the initial phase, it is difficult to correctly start the rhythmic muscle movements that are the main exercises, and then do it. These exercises.

The purpose of the invention is the provision of optimal physical activity during various types of exercises with a complex rhythm of muscle movements.

This goal is achieved by the fact that in a device for determining physical activity, which contains a sequentially connected heart rate measuring unit, an adder, a decoder, a comparison unit, a reversible counter, the output of which is connected to a counting input ··. adder connected to the output of the decryptor by its input, a matching circuit block connected to its other input by its output, an interval shaper of • the time the commands follow, and a block of stimuli connected to the matching circuit block, a binary frequency and conversion factor setting unit, binary a counter, an additional decoder, a unit for setting the ratio of time intervals, consisting of a series-connected switch and an OR element, and an additional matching circuit, while the input d binary. of the counter is connected to the output of the matching circuit block and to the second input of the additional matching circuit, the input of which is connected to the input of the stimulus block, the additional input of which is connected to the first input of the additional decoder, all outputs of which are connected to the outputs of the frequency setting block! And the conversion factor, the second output which is connected to the input of the shaper of the time interval following the commands.

The drawing shows a structural diagram of a device for determining physical activity.

The device comprises a heart rate measuring unit 1, an adder 2, a decoder 3, a comparison unit 4, a reversible counter 5, a coincidence circuit unit 6, a sequence follower 7, a binary counter 8, a decoder 9, a frequency setting unit 10, and a conversion factor , block 11 sets the ratio of the time intervals, pattern 12 matches, block 13 stimuli. Moreover, block 11 consists of a series-connected switch and an OR element. In this case, the pulse rate measuring unit 1, the adder 2, the decoder 3, the comparison unit 4 and the reversible counter 5 are connected in series. The output of the decoder 3 is also connected to the input of the block 6 matching schemes, the other input

876 1.08 _{4 of} which is connected to the output of the shaper 7 of the time interval for following the commands, and the output is connected to the counting input of the binary counter 8 and to the first input _{5 of the} matching circuit 12. Another input of the circuit 12 is connected to the output of the block 11.. Setting the ratio of the time intervals, and the output to the first input of the block 13 of the stimuli.

The output of the binary counter 8 is connected to the input of the decoder 9, the outputs of which are connected to the inputs of the unit 11 for setting the ratio of time intervals l in parallel to the inputs of the unit 10 for setting the frequency and conversion factor, 'one output of which is connected to the installation input of the binary counter 8, and the other to the installation the input of the shaper 7 time interval of the sequence of commands. The second input of the block 13 of stimuli is connected to the first output of the decryptor> Rator 9.

The device operates as follows.

Before starting the patient to perform physical exercises in block 4 of the comparison set the specified (reference) value of the heart rate.

If a complex rhythm of movements is selected during the exercises, then the switch of the unit 10 for setting the frequency and conversion factor is set to the half that corresponds to the number of rhythmic movements in their repeating cycle and with the correlation of the time intervals in this complex rhythm. Thus, the number of command signals in their cycle, which are then generated by this device when the patient is working with it, is pre-set, as well as the ratio of the time interval® between the teams for a given training session. signals.

For example, if the number of command signals in their cycle is four, and the ratio of time intervals between these signals is set as 1: 1: 2: 1, then in this case the switch of block 10 is set to 1 + 1 + 2 + 1 ^ 5.

Moreover, in the block 11 setting the ratio of the time intervals of the switch, installed in the output circuits of the decoder 9, set. to the position corresponding to the selected ratio (1: 1: 2: 1).

In our example, the first, second, third, and fifth toggle switches are turned on. The fourth toggle switch remains off, since the time interval between the third and fourth command signals should be doubled (for example, if it was necessary to observe the ratio of time intervals between command signals as 1: 3: 1: 1, then this * · 5 but it would include the first, second, fifth and sixth toggle switches).

When the patient is working with the device, the value of his heart rate measured by the heart rate measuring unit 1 is recorded in adder 2 at certain time intervals and the code of the recorded number is fed to the decoder input

3. From the output of the decoder 3, the enable signal is supplied to the corresponding input is of block 6 of the coincidence circuit, the other input of which receives pulses of time (scale) marks from the shaper 7 of the Time interval for following the commands.

If a simple rhythm of M movements is specified, then the switch of the frequency and conversion factor setting unit 10 is set to the first position, and then the frequencies of the driver generator of the shaper 7 time intervals of 25 commands will be equal to the initial frequency determined by the program * of the device, and the conversion factor of the binary counter 8 will be equal to one. The pulse arriving at the input of the binary counter 8 ЗО, passing simultaneously to the first input of the matching circuit 12, at the second input of which there is already an enable signal from the zero output of the decoder 9 (since the binary counter 8 was ₃₅ in the initial zero state), starts the block 13 of irritants and with its slice it writes 1 in the binary counter 8. ''

I Since the switch unit 10 usta- ₄₀ Novki frequency and conversion ratio in a first position, a binary counter 8 again established in the original zero position, and when entering the input of the next counter signal _"45 described process again repeated. In this case, the frequency of command issuing by block 13 of the scavengers will be determined by the program of the device and the value of the pulse rate of the patient, recorded in adder 2 until the next measurement cycle.

If the patient’s pulse rate will correspond to the reference value of the frequency recorded in the comparison unit 4, then in this case, the frequency of command signals from block 13 of stimuli ^{55 to the} patient will be determined by the program stored in the device. If the pulse rate will differ from the reference value, when it is received (during the next measurement) at the input of the comparison unit 4 from the output of the decoder 3, the pulse frequency in the comparison unit 4 will generate a signal arriving at the counter 5 in the addition mode, if heart rate value exceeds the reference.

If the patient’s pulse rate is less than the reference value, then a signal will be generated in the comparison unit 4, which will be sent to the reverse counter 5 in the subtraction mode. Arriving at the counting input of adder 2, the value of the number recorded in the reverse counter 5 is added to the try frequency code in adder 2 and in the adder 2, and the sum code is input to the decoder 3, changing the frequency of the signals. coming from the output of block 6 coincidence schemes to the input of the binary counter 8. Thereby, the rate of exudation of physical exercises, set by the block 13 of scavengers, changes.

If the patient’s heart rate exceeds the reference value, the rate set by the device decreases, and when the heart rate is lower than the reference, this rate increases. _z

If muscle movements with a complex rhythm are performed, then the device control switches are set in accordance with this rhythm (examples are described).

In our example, the switch of the unit 1O of the installation is set to the position ”5 ^β .

In this case, the frequency of the master oscillator of the shaper of 7 intervals of the sequence of commands will be increased by five times, and, accordingly, with the same value of the pulse rate, pulses with a frequency of five times greater will come from the output of the block 6 matching circuits. Since the conversion factor of the binary counter 8 in this case will also be five, this counter will be set to its original state after the fifth pulse is written to it (in this case). In this case, the pulses to the second input of the coincidence circuit 12 will be supplied in accordance with the data recorded in the binary counter 8 hours from the first ”second and so on, to the fifth outputs of the decoder 9 through the toggle switches and the OR circuit of the unit 11 for setting the ratio of time intervals.

If the toggle in the corresponding circuit of the decoder 9 is turned on, the pulse passes to the input of the matching circuit 12.

If this toggle switch is disabled, then the signal does not pass to the input of the matching circuit 12 and, as a result, the stimulus unit 13 does not work. In accordance with the 'accepted in a specific example, the ratio of the time intervals between the command signals for the patient (1: 1: 2: 1) include the first, second, third and fifth toggle switches. Now, when the first pulse appears at the output of block 6 of the matching circuit, it enters the first input of matching circuit 12, at the second input of which there is a resolving potential from the first output of the decoder 9.

Block 13 of stimuli) gives an accentuated first signal in their cycle, since at its second input there is a signal from the first output of decoder 9.

By a slice of the pulse received at the input of the binary counter 8, a single is written into it and the resolving signal from the second output of the decoder 9 through the second toggle switch and the ILL circuit is received as a result of the co-ownership circuit 12.

When the next pulse coincides with the next pulse at the output of block 6, it will again pass to the input of block 13 of stimuli, which produces an unaccented command signal. Similarly in binary—; counter 8 will record one more unit and the resolving potential will appear at the third output of the desiccator 9. This will be repeated until the fourth pulse coincides with the output of block 6, which does not enter the input of block 13 of irritating gels, since the fourth toggle switch in our case, in accordance with the selected ratio of 1: 1: 2: 1 is not included.

Therefore, the third time interval will last twice as long, which is required in this case when performing the complex rhythm of the patient's muscular movements. The fifth impulse again enters the input of block 13 of stimuli, thereby instructing the patient to stop the previous movement and start the next, shorter one in this case.

By slice of this fifth pulse, the fifth unit is written to binary counter 8 and cn is set to the initial zero state by a signal from the frequency and conversion factor setting unit 1O. Further this cycle will be repeated. In the case of a complex rhythm of movements 5, the tempo of their execution will be regulated in the same way as with the device described above in the case of installing it for the patient to perform movements with a simple (uniform) rhythm, but at 10 this will remain constant regardless of the change the frequency of the command signals, a predetermined ratio of time intervals between them.

The device provides the ability to perform physical exercises with a complex rhythm of movement, while at the same time providing optimal (depending on the patient's pulse rate) ²⁰ physical activity.

Claims (1)

(54) DEVICE FOR DETERMINATION The invention relates to medical technology and can be used for short and experimental purposes. According to the main author. St. M 665892 discloses a device comprising a pulse frequency measurement unit, a reversible counter, a comparison unit, a frizzler of the command time interval and a successively coupled adder, a decoder, a coincidence circuit block, and a stimulus block, with the Aeshi input ({| the comparison unit and the reversible counter are connected to one of the inputs of the adder, the other input of which is connected to the output of the pulse rate measuring unit, and the output of the shaper of the command follow time is connected to the input of the block However, the known device does not allow the patient to perform a complex rhythm of the movements. This is because the known device gives the command evenly (like the method of loading) only by changing their frequency. For performing the same physical exercises that have a complicated; rhythm of movements, uneven intervals between command and signals are required, corresponding to the duration of muscle movements in the patient’s complex, holistic action. It is known that temporal characteristics of muscle movements include their duration, pace, and rhythm. The rhythm of movements is a measure of the correlation of phases, a complex characteristic of movement, organizing its separate phases into a single holistic action. The ratio in the sequence of these phases is not known device. In addition, this device also does not take into account the presence of two phases in physical exercise accentuated, which is especially important when performing physical exercises with a complex rhythm, since without accentuation, for example, the initial phase, it is difficult to correctly start complex rhythmic muscle movements, Then, plow & gy exercise. The purpose of the invention is to provide optimal physical activity for various types of exercises with a complex rhythm of mouse movements. The goal is achieved by the fact that a device for determining physical activity, which contains a sequence. pulse rate measuring unit, adder, decoder, comparison unit, reversible counter, the output of which is connected to the counting input of the adder, connected to the output of the deshi (} rator with its input, the circuit of the matches with its input, connected to its other input, driver output the interval of time for following the commands, and connected to the block of diagrams of the coincidence block, the disconnectors are entered, sequentially are connected to the frequency setting block and the coefficient (} of the recalculation, the binary counter, the sub decoder, the cooler time intervals, consisting of a series of interconnected switches and an OR element, and an additional matching circuit, with the binary counter input connected to the output of the matching circuit block and the second input of the additional matching circuit, whose input is connected to the input of the stimulus block The auxiliary input of which is connected to the first input of the additional decoder, all the outputs of which are connected to the outputs of the conversion frequency setting unit jH, the second output of which is connected to the input of the form ovatel slot sequencer komanr. The drawing shows a block diagram of a device for determining physical activity. The device contains a pulse rate measurement unit 1, an adder 2, a decoder 3, a comparison unit 4, a reversing counter 5, a matching circuit unit 6, a command follower interval 7, a binary counter 8, a distance meter 9, a frequency setting unit Yu, and a conversion factor, the time interval ratio setting unit 11, the coincidence circuit 12, the stimulus unit 13. Moreover, block 11 consists of a series of but connected switches and an OR element. In this case, the unit 1 for measuring the frequency band, the adder 2, the decoder 3, the block 4 for comparison, and the reversible counter 5 are connected in series. The output of the decoder 3 is also connected to the input of block 6 of the matching circuit, the other input of which is connected to the high end of the command follower interval 7, and the output connected to the counting input of the binary counter 8 and to the first input of the matching circuit 12. The other input of the circuit 12 is connected to the output of the unit 11 for setting the ratio of time intervals, and the output to the first input of the block 13 stimuli. The output of the binary counter 8 is connected to the input of the decoder 9, the outputs of which are connected to the inputs of the setting unit 11, the ratio of time intervals l pairwise to the inputs of the unit Yu setting the frequency and the conversion factor, one output of which is connected to the installation input of the binary counter 8, and the other - to the installation input of the driver 7 of the time interval for following the commands. The second input of the block 13 of stimuli is connected to the first output of the decoder 9. The device operates as follows. Before the patient begins to perform physical exercises, in block 4 of the comparison, a predetermined (reference) value of the pulse rate is established. If a complex rhythm of movements is chosen when performing exercises, the switch of the frequency setting block 1 and the conversion factor is set to the position that corresponds to the number of rhythmic movements in their repeated cycle and the ratio of time intervals in this complex rhythm. Thus, the number of command signals in their cycles is set beforehand, then generated by this device when the patient is working with him, as well as the ratio between the time between command signals and signals that is constant for a given training session. For example, if the number of command signals in their cycle is four, and the ratio of the time intervals between these signals is set to 1: 1: 2: -1, then in this case the switch of unit Yu is set to l + l-t2 + l-5 . In this case, in the setting unit 11, the ratio of the time intervals of the switch installed in the output circuits of the decoder 9 is set. in the position corresponding to the chosen ratio (1: 1: 2: 1). In our example, the first, second, third and fifth toggle switches are included. At the same time, the fourth toggle switch remains off, since the time interval between the third 58 and the fourth comma signal will be doubled (for example, if you had to observe the ratio of time intervals between command signals 1: 3: 1: 1, then It would include the first, second, fifth, and sixth toggle switches). When a patient is working with a device, the frequency of his pulse, measured by the I pulse frequency measuring unit, is recorded at regular intervals into the adder 2, and the code of the recorded number is fed to the decoder 3 output. From the output of the 4th output 3, the enable signal is fed to the corresponding block input 6 coincidence circuits, to the other input of which impulses of temporal (scale) marks arrive from the imaging unit 7 of the time interval for following the commands. In case a simple rhythm of movements is set, the switch of the frequency setting and conversion factor set 1O is set to the first position, and the frequency generator of the master oscillator of the 7 command time intervals will be equal to the frequency determined by the operation program of the device, and the ovoid conversion recalculate counter 8 will be equal to one. A pulse arriving at the input of the binary counter 8, which passes simultaneously and to the first input of the matching circuit 12, at whose input there is already a permitting signal from the zero output of the decoder 9 (since binary counter 8 is in the initial zero state), triggers block 13 and, with its slice, it records 8 units in a binary counter. 1 Since the switch of the frequency setting and conversion ratio unit 1O is in the first position, binary counter 8 is again set to the initial zero position, and when this counter is received at the most accurate counter, the described process will repeat again. At the same time, the frequency of commands issued by the unit 13 of disintegrators will be determined by the program of operation of the device and the value of the patient's pulse rates recorded in the adder 2 until the next cycle of ik "ep {i. If the patient's pulse rate corresponds to the reference value recorded in block 4 of the comparison I, then in this case the frequency of the command signals sent by the stimulus block 13 to the patient will be determined by the program embedded in the device. If the pulse rate differs from the reference 86 value, then when entering (at the next measurement) n input of the comparison block 4 from the output of the decoder 3 pulse rate values in the comparison block 4, a signal will be generated that goes to the reversible counter 5 in the addition mode, in the case if the pulse rate value exceeds the reference. If the frequency of the patient's pug. Is less than the reference value, then in block 4 of the comparison, a signal will be generated that arrives at the reversible counter 5 in the subtraction mode. The input to the counting input of the adder 2, the value recorded in the reversible counter 5, is added with the code of the putl frequency in the adder 2, and the amount of the sum goes to the input 4 and the frequency of the signal received from the output of block 6 of the coincidence circuit to the input binary counter 8. Thus, the rate of exercise taken out by the block of 13 stimuli to the patient changes. When the pulse frequency rises, the rate set by the device decreases, and the pulse rate below the reference one increases. If muscle movements are performed with a complex rhythm, the control switches of the device are set in accordance with this rhythm (examples are described). In our tfnmer, the switch of the installation unit 1O is set to half-aisenin 5. At that, the frequency of the master oscillator of the driver 7 command follower intervals is increased five times, and, accordingly, at the same pulse rate from the output of the unit 6 circuits syo with aotota five times. Since the conversion rate of the eotic counter 8 in this case is also equal to five, this counter will be installed in the same manner after writing (in this case) the fifth pulse into it. In this case, the pulses to the second input of the coincidence circuit 12 will come in accordance with the scrapping from the first second, recorded in the binary counter 8 h1, etc. to the fifth outputs of the decoder 9 through the toggle switches and the OR circuit of the installation unit 11 of the related time intervals, If TyM6jKp in the corresponding circuit of the decoder 9 is turned on, the impulse passes to the input of the coincidence circuit 12. Zero this toggle switch is turned off, then the signal does not pass to the input of circuit 12 and as a result, block 13, annoying, will not work. In accordance with the ratio of the time intervals between patient signals for the patient (1: 1: 2: 1) adopted in the specific example, the toggle switches first, second, third and fifth are included. Now, when the first pulse at the output of block 6 of the circuits coincides, the NIN arrives at the first input of the 12 Coincidence circuit, at the second input of which there is a resolving potential from the first output of the decoder 9. The stimulus 13 block produces the accentuated first signal in their cycle , since at its second input there is a signal from the first output of the decoder 9. By a pulse cut that arrives at the input of binary counter 8, a unit is written to it and to the second input of the constellation circuit 12 the result is a decisive signal from the second output decoder 9 via the second OR gate and the toggle. With the appearance at the output of block 6 of the schemes of the next pulse it coincides. again, the entrant 13 times, which is not accentuated, the command signal / and again, will pass to the block. Similarly, one more unit will be written to the dual counter 8 and the resolving potential at the third output of the decoder 9. This will be repeated until / cini does not reach the output of block 6 of the fourth pulse coincidence circuit, which does not hit the input of block 13 of stimuli, since the fourth in our case, in accordance with the chosen ratio of 1: 1: 2: 1, is not included. Consequently, the third time interval will last twice as long, which is what is required in this case when performing the lamellar rhythm of the patient's muscle movements. The fifth impulse again goes to the input of the block of 13 razrazhigel, thereby giving the patient the command to stop the movement and begin a shorter, shorter one in this case. By a slice of this fifth pulse, binary unit 8 will write down the unit and w will be set to the initial zero state by a signal from block 1O of the frequency setpoint and the conversion factor. This cycle will then be repeated. In the case of a complex rhythm, the rate of their chick infestation will be dulled in the same way as in the description of the above work of the device in case it is installed to perform a pasynth-like motion with a simple (uniform) rhythm, but at the same time it will remain constant outside The dependence on the change in the frequency of giving command signals is a predetermined ratio of the time intervals between them. The device provides the ability to perform physical exercises with a complex rhythm of movements, while at the same time providing the optimal (depending on the frequency of the patient's throat) physical activity. The invention is a device for determining physical activity (L load according to the author St. N 665892, that is, CHT1L in order to ensure optimal physical load. For various types of exercises with complex rhythms of muscle movements, it is entered in series with a frequency setting and a conversion factor unit, a daoichny counter, an additional decoder, a time interval ratio setting unit consisting of a series-connected switch and an OR element, and an additional matching circuit. D binary counter Connected to the output of the matching circuit block and to the second input of the additional matching circuit, the output of which is connected to the input of the block of stimuli, the additional input of which is connected to the first output of the additional decoder, all outputs of which are connected to the inputs of the frequency setting and recalculation coefficient input, the second output which is connected to the input of the driver of the time interval following the commands Sources of information taken into account during the examination 1. USSR Author's Certificate No. 665892, cl. A 61 B 5/10, 1976.