RU2008800C1 - Method and device for checking hearing - Google Patents

Abstract

FIELD: medicinal engineering. SUBSTANCE: method of checking hearing of single or several patients concludes in forming sequences of test sound signals with preset duration, amplitude and frequency, according to number of tested patients. These signals act on hearing of patients and reaction of patients is analyzed to test sound signal. Parameters of each sequent test sound signal of the sequence are determined from the results of testing of patient to previous signal. Analysis of patient's reaction to test sound signal is carried out directly after the reaction is achieved, and sound signal interrupts. If the patient doesn't react on the signal, analysis is carried out later preset time interval t_a, which is counted from the beginning of generation of sound signal and excess over duration of its sounding t_c. Audiometer has central processor unit, sonic generator, test sound signal former, amplifier provided with commutator, phone sets, patient's buttons and mating unit, test sound signal interval timer which has input connected with central processor unit, on-line and permanent memories, unit for checking patient's reactions which has input connected with mating unit and output connected with central processor unit. All the members of the circuit are connected in series. Outputs of on-line and permanent storages are connected with central processor unit. Number of test sound signal interval timers corresponds to number of patients under testing, as well as to number of brought patient's reaction interval timers and pause timers between test sound signals, which have inputs connected with central processor. Unit for checking patient's reaction is made in form of priority interruption unit. The first group of inputs of this unit is connected with outputs of mating unit, the second group of inputs is connected with outputs of timers. The first and the second outputs of central processor are connected with corresponding second inputs of test sound signal former and with amplifier provided with commutator. EFFECT: reduced duration of checking. 9 dwg

Description

 The invention relates to automatic monitoring of the functional state of the hearing organs of people and can be used when examining a significant number of people, for example, during preventive medical examinations of workers at factories with a high noise level, and also to devices for conducting this kind of control, called audiometers.

 Known methods of audiometry and audiometers for their implementation, allowing for simultaneous examination of several subjects. So, in the patent application of Germany N 2300872, class. A 61 5/12 describes an audiometer in which, during a given time interval (action time), a test sound signal is generated with a constant frequency and level for a given action time, which is simultaneously transmitted to several headphones. If the subject received the test signal, then he presses the button. The button press is recorded together with information about the place where the button was pressed and about the parameters of the test signal (frequency, level). In a slightly improved modification, an audiometer of the type described is also known from the application of Germany N 2704846, class. A 61 B 5/12, published in 1978

 The disadvantage of the method of audiometry used in these devices is that when conducting research, the selection of the parameters of each examining test sound signal does not depend on the test subject's response to the previous signal, and therefore patients are forced to undergo a large number of unnecessary tests, which leads to their fatigue, errors and an increase in the total duration of the examination.

 More perfect is a method for the simultaneous monitoring of the hearing of several patients, used in the audiometer described in British patent application N 2157474, class. A 61 B 5/12, published in 1986, according to which, depending on the number of simultaneously examined patients, a certain number of sequences are formed from test sound signals of a given duration, amplitude and frequency, and the ratio of patients to acting test sound signals is analyzed by the presence or their lack of an appropriate reaction. In this case, the parameters of each subsequent test sound signal of the generated sequence of test sound signals are set based on the analysis of the relationship of the corresponding patient to the previous signal. As a result, each patient receives his own individual sequence of test sound signals, which, when rationally taken into account the results of previous tests, leads to a significant reduction in the total number of tests, reduction in patient fatigue and increase the reliability of the examination.

 The disadvantage of this method is that the tests of all patients are subordinated to the same predetermined rhythm, determined by the fact that it strictly and uniformly sets for all patients the time interval between the supplied test signals, and this, given the uneven reaction speed, manifested both by different and by the same patient, leads to waste of time.

 Reducing the duration of the examination is achieved by the fact that when controlling for hearing by supplying acoustic signals of a given duration, amplitude and frequency to analyze the patient’s attitude to the previous acoustic signal, in contrast to the prototype method, the patient’s attitude to the acting acoustic signal is analyzed and the latter is stopped immediately following the reaction of the patient, and in the absence of reaction - after a specified interval of time, counted from the beginning of the stim ul and exceeding its duration.

 These distinctive features make it possible to use the psychomotor features of subjects to accelerate hearing control.

 For persons with a sufficiently high speed of response to sound stimuli, it becomes possible to reduce the overall duration of the audiometric control by reducing the duration of individual tests.

 For persons with insufficiently fast reaction time, a reduction in the duration of the audiometric control is achieved by providing the subject with additional time to press a button, making it possible to correctly take into account tests whose reaction time exceeds the duration of the acoustic signal. And this avoids iteration and reduces the total number of tests.

 These distinctive features of the proposed method for hearing control are significant, which is confirmed by the lack of information about their use in similar technical solutions known from patent and special technical and medical literature. To implement the proposed method for hearing control, an audiometer is proposed that improves a similar device and implements the hearing control method described above, selected as a prototype.

 The audiometer selected as a prototype is intended for the simultaneous examination of several patients. It contains serially connected central processing unit, sound generator, test sound generator, amplifier with switch, telephones, patient buttons and interface unit, interval interval of test audio, connected at the input to the central processing unit, patient response analysis unit connected to the inputs a pairing unit and an output with a central processing unit, permanent and random access memory connected at the outputs to a central processing unit th device. The patient response analysis unit is made in the form of a multiplexer, which determines the necessary sequence of interrogation of its inputs at the command of a timer setting the general rhythm and the associated overhead of time for examining the patients.

 The noted drawback is eliminated and the reduction in the duration of the examination is achieved by the fact that in an audiometer containing a centrally connected central processing unit, a sound generator, a test sound shaper, an amplifier with a switch, telephones, patient buttons and a pairing unit, a test sound interval timer connected at the input with a central processing unit, a patient response analysis unit, connected by inputs to the interface unit and an output with a central processing unit By construction, permanent and operational memory devices connected at the outputs to the central processing unit, in contrast to the prototype audiometer, the number of time intervals of the test sound signal corresponds to the number of subjects and the number of timers for the interval of the patient’s reaction and the pause timers between test audio signals connected at the input with a central processing unit, and the patient response analysis unit is designed as a priority interrupt unit, the first group of inputs of which connected to the outputs of the interface unit, and the second - to the outputs of timers, wherein the first and second outputs of the central processing unit are respectively connected to second inputs of the test tone generator and an amplifier with a switch.

 In FIG. 1 presents a structural diagram of the proposed audiometer; in FIG. 2-8, respectively, examples of the implementation of the main blocks of the audiometer: a central processing unit, a sound generator, a driver of a test sound signal, an amplifier with a switch, a pairing unit, a block of priority interrupts and timers; in FIG. 9 is an enlarged structural diagram of the algorithm of the central processing unit.

 The audiometer contains serially connected central processing unit (CPU) 1, sound generator 4, driver 5 of the test audio signal, amplifier 6 with a switch, telephones 7, and blocks 5 and 6 are connected to the inputs of CPU 1. The number of sets of telephones 7 corresponds to the nominal number of subjects patients. According to the number of telephones in the audiometer, there are 8 patient buttons, the outputs of which are connected through the interface unit 9 to the priority interrupt unit 10. The latter contains a number of inputs associated with the outputs of the timers 11, 12, 13, respectively, of the intervals of the test sound signal, the patient's response and the pause between the test sound signals. The number of timers of each of the groups 11, 12, 13 corresponds to the number of buttons 8 of the patient. Priority interrupt unit 10 is connected at the output to the CPU 1, to which timers 11, 12, 13 are connected at the input. The audiometer also contains read-only memory (ROM) 2 and random access memory (RAM) 3 for storing both the control program and the constants and research results. ROM 2 and RAM 3 are functionally connected to the CPU 1. To provide information about the performed audiometric studies, the device has a printing device 14. For visualizing data and entering additional data and programs, a keyboard and indication unit 15 is provided.

 CPU 1 (Fig. 2), for example, may contain a clock clock 1.1, a microprocessor (MP) 1.2, connected at the input to the clock generator 1.1, buffer amplifiers 1.3, 1.4 addresses and data associated with the input, respectively, with the address and information outputs of MP 1.2 and the output connected together with the control signals MP 1.2 to the ROM blocks 2, RAM 3 and the output register 1.5. The operation of the generator 4, the shaper 5 and the amplifier 6 with the switch, as well as the timers 11, 12, 13 are controlled by the MP 1.2 through the output register 1.5 by issuing a parallel binary control code to the corresponding unit.

 Sound generator 4 (Fig. 3), implemented, for example, according to a scheme with a VIN bridge, may contain a switch 4.1, RC-links (the number of which is determined by the number of generated frequencies) connected at the outputs to the switch 4.1 and combined at the input, amplifier 4.2, connected to the output of the switch 4.1 and the inputs of the RC links. The choice of the frequency of the sound signal of the generator 4 is controlled by switching one of the RC links to the input of the amplifier 4.2 through the switch 4.1, controlled by the frequency selection code from the output of the register 1.5 of the CPU 1.

 Shaper 5 of the test audio signal may, for example (Fig. 4), contain an attenuator 5.1, made in the form of a resistor voltage divider with a step of 5 dB, a switch 5.2 connected by information inputs to the outputs of the attenuator 5.1, and the intensity control inputs to the output of the register 1.5 CPU 1, the driver of the leading and trailing edges (trapezoidal envelope shape) of the test sound signal made on optocouplers OEP1, OEP2, controlled through elements NOT by the pulse of the duration of the interval of the test sound signal. The duration of the rise and fall fronts of the test audio signal is provided by the inertia of the optocouplers.

 Amplifier 6 with a switch (Fig. 5) contains, for example, amplifier 6.1 and switch 6.2 connected in series, the latter connecting the output of amplifier 6.1 to the phones of the right ear, depending on the telephone selection control code coming from the output of register 1.5 of CPU 1.

 Block 9 interface is, for example, a well-known anti-bounce circuit implemented on RS-flip-flops (Fig. 6).

 Block 10 priority interrupt, implemented, for example, in the form of a single-chip LSI type КР580ВН59, contains (Fig. 7) a buffer amplifier 10.1, block 10.2 I / O control, register 10.3 service, encoder 10.4 priorities, register 10.5 requests, register 10.6 mask interrupt. Block 10 operates in a fixed priority mode, with interrupt inputs from timers 11 having a higher priority. . thirteen.

 Blocks 11.. . 13 are of the same type and can also be implemented, for example, in the form of a single-chip LSI of type KR580VI53, containing (Fig. 8) a buffer amplifier 11.1, an input-output control unit 11.2, a mode register 11.3, counters 11.4. . . 11.6. All timers operate in a single-vibrator mode, and the start of counters is 11.4. . . 11.6 operating in reverse mode is carried out by the control code from the output register 1.5 of the CPU 1.

 The described audiometer works as follows. According to the program stored in ROM 2 and the algorithm structure of which is shown in FIG. 9, the CPU 1 controls the sound generator 4 and the driver 5, which control the frequency and amplitude of the test sound signal, and also form the leading and trailing edges of the sound package. Then, through an amplifier 6 with a switch, the signal is sent to one or more phones 7.

 Simultaneously with the start of the test sound signal, the CPU 1 starts the timers 11 and 12, respectively, of the intervals of the test sound signal and the patient's response. The response signal of the test subjects, generated by the patient's buttons 8, enters through the interface unit 9 to the first part of the interrupt inputs of the priority interrupt unit 10. The second part of the interrupt inputs of block 10 receives signals from the outputs of the timers 11.. . 13, forming the intervals of the test sound signal, the patient's response and the pause between the test sound signals. Interval durations are set by CPU 1.

 When you press any of the buttons 8 or at the end of any of the intervals, block 10 generates an interrupt request signal that arrives at the corresponding interrupt request input of CPU 1, after which the latter, in accordance with the above structure of the algorithm, goes to the processing routine of the corresponding interrupt level. When several requests arrive, interrupt processing is carried out in accordance with the given priorities. Upon receipt of a signal from any of the buttons 8 of the patient, the CPU 1 stores in RAM 3 the number of the pressed button and the corresponding values of the amplitude and frequency of the supplied test sound signal, resets the corresponding timers 11 and 12, and starts the timer 13.

 When a signal arrives at block 10 from the output of the timer 11 of the test audio interval, the corresponding pause interval timer 13 starts, when a signal is received at the input of block 10 from the output of one of the timer 12 of the patient response interval in RAM 3, the number of the unpressed button and the corresponding amplitude values are stored and the frequency of the test sound signal that did not cause the patient’s reaction, and when a signal is received at the input of block 10 from the output of one of the timers 13 of the interval of a pause between test sound signals the next interval of the test sound signal is formed and the timers 11 and 12 are started again. In this case, the frequency and level of the next parcel are set by CPU 1 based on the data on the patient’s response to the previous parcel in RAM 3 according to a subroutine based on one of the known methods, for example, by parametric estimation using sequential testing. Based on the data on the amplitudes of the test sound signal at the same frequency, the CPU 1 determines the patient’s hearing threshold at a given frequency, the data of which is recorded in RAM 3. The full amount of information about the patient’s hearing thresholds at all test frequencies is displayed at the end of the examination in the form audiograms to the indicating device of the keyboard and indication unit 15 or the printing device 14. The input data and operating modes are input using the keypad of the block 15.

 Since, thanks to the invention, it has become possible to ensure that the button is pressed and a new test is started at any time within the interval of the test audio signal, depending on the speed of the test person’s reaction, it became possible to shorten the duration of a significant number of tests accompanied by pressing the patient’s button and thereby reduce the overall examination duration. The examination time was also reduced by providing patients with a longer interval for a reaction to the test sound signal, which helps to reduce the number of unnecessary iterations when examining people with a delayed response to sound stimuli. In accordance with the calculations, the implementation of the invention will reduce the total duration of audiometric examinations by 15-20% compared with the method selected as a prototype. (56) UK patent N 2177474, CL. A 61 B 5/12, 1986.

Claims (2)

 1. A method of controlling hearing by supplying acoustic signals of a given duration, amplitude and frequency to analyze the patient’s attitude to the previous signal, characterized in that, in order to reduce the duration of the examination, the patient’s attitude to the acting acoustic signal is analyzed and the latter is stopped immediately after the reaction patient, and in the absence of reaction - after a specified interval of time, counted from the beginning of the stimulus and exceeding its duration.  2. An audiometer for hearing control, comprising a central processing unit, a sound generator, a test sound generator, an amplifier with a switch, telephones, patient buttons and a pairing unit, a test sound interval timer connected to the input by a central processing unit, a reaction analysis unit a patient connected to the inputs with the interface unit and the output to the central processing unit, read-only and read-only memory devices connected to the output mi with a central processing unit, characterized in that the number of interval timers of the test sound signal corresponds to the number of subjects and the number of timers for the interval of the patient’s reaction and the pause timers between the test audio signals connected to the inputs of the central processing unit, and the patient response analysis unit is made in the form of a block priority interruptions, the first group of inputs of which are connected to the outputs of the interface unit, and the second - with the outputs of timers, while the first and second the outputs of the Central processing unit are connected respectively to the second inputs of the shaper test audio signal and an amplifier with a switch.

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