JPH0432661B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an electronic auscultation/diagnosis device, and in particular,
The present invention relates to an electronic auscultation/diagnosis device suitable for use in a so-called real-time multiplex electronic auscultation/diagnosis system. The feature is that it has one or several stethoscopes and one microcomputer device to transmit the signal, and the audio signal acquired by the stethoscope is transmitted so that it can be heard by other stethoscopes at the same time. The microcomputer device is characterized by being able to compare the measured sound signal with the reference sound signal and analyze the isochronism of the signal, and provide it for reference to the person visiting the hospital.

In general, the audio frequency and amplitude of audio signals generated due to fluid flow (e.g. blood, air, water, etc.) or solid motion (linear motion, rotation, point, or vibration) in the human body (or equipment), etc. Detection and amplification are performed based on the frequency and period, etc., and a determination of a normal state or an emergency state can be obtained based on experience or inference through the auditory sense of the measurer. Furthermore, it is also possible to diagnose the cause of the abnormality and the importance of the site where it occurs, and provide it as a reference for treatment or repair. The method described above is called the auscultation method. The auscultation method is currently the most commonly used failure diagnosis method by doctors and equipment maintenance engineers, and has already become a habit, and although its principles are not profound, it is absolutely related to the experience of the diagnostician. However, there are many mistakes made in actual application.

For example: (1) When the auscultator's hearing is heavy (for example, a geriatric doctor), the patient's weak sounds transmitted from a traditional stethoscope are often difficult to hear, causing diagnostic difficulties.

(2) When an auscultator (doctor) uses a stethoscope, there is no way to compare the patient's normal body sounds (under healthy conditions), so there is no way to compare them; however, the body sounds of each person are never the same. Rather, one person's body sounds under normal conditions may be the same as, or even the opposite of, another person's body sounds under diseased conditions. Therefore, there is no way to compare an individual's body sounds when he is sick with his own body sounds under his own health conditions, and current stethoscopes cannot provide such comparative information. Can not. Furthermore, if it is left to the auscultator's subjective judgment based on body sounds heard in the past, there is no doubt about the accuracy of the judgment result.

(3) When a doctor uses a stethoscope, he must always compare the sound prints (sound frequency records) with the sound print patterns of various diseases that he has already memorized in his mind, and he must compare them with the sound print patterns of various diseases that he has already memorized in his mind. From the point of view of a shallow doctor, I don't have enough memories to compare it to, so I can't make a diagnosis. On the other hand, even experienced doctors sometimes forget certain patterns and make diagnostic errors. In the doctor's opinion, patients with abnormal body sounds due to poor health or illness may be diagnosed incorrectly because there is no data to compare them with.

(4) From the intern's perspective, when performing auscultation, it is necessary to repeatedly listen to various patients and healthy people under the guidance of an experienced doctor and gain experience. However, it is also a nuisance from the standpoint of the sick people to study for the sick (or the healthy).

(5) A stethoscope is a professional instrument used by doctors, and it is difficult for the general public (whether they are healthy or patients) to judge whether they are healthy or not using a stethoscope on their own. This is very inconvenient for people who live in areas that are inconvenient and lack doctors.

(6) If the doctor himself encounters a medical condition that he has never diagnosed before, it is almost impossible to diagnose it using a stethoscope (there is no way for an intern to know about a medical condition that he has never experienced). Also,
Even if a doctor is an experienced doctor, it is difficult to distinguish the disease using a stethoscope, even if the patient is an experienced doctor.

(7) Malfunctions and internal and external damage to machinery and structures can be diagnosed using a stethoscope, but experienced diagnostic technicians are difficult to find.

The present invention was developed in order to solve the above problem, and is an electronic auscultation/diagnosis system that records and stores various audio signals, allows more people to auscultate simultaneously, and uses a microcomputer device to assist the auscultation and make judgments. The present invention provides an electronic auscultation/diagnosis device that can be used not only for medical purposes (humans, animals, etc.) but also for diagnosing various devices and structures.

Next, one embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 shows the overall configuration of an electronic auscultation/diagnosis device according to an embodiment, of which the configuration of a stethoscope is shown in FIGS. 2 and 3.

In these figures, the stethoscope includes an audio/electrical converter 1, a preamp 2, a bandpass filter 3, a signal amplifier 4, a function and part sector 5, an electrical/audio converter 6, a high frequency enhancer 7, modulator 8, antenna 9, demodulator 10,
De-emphasizer 1
1, a balancing net circuit 12, a recorder device 13, a power supply device 14, a sound guide tube 15, etc.

Figure 4 also shows the electronic auscultation system in this embodiment.
The configuration of the main body of the diagnostic device is shown. In the figure,
The main body of the electronic auscultation/diagnosis device includes an antenna 21,
Demodulator 22, de-emphasizer 23, band pass filter 24, narrow band band pass filter 25, full frequency rectifier 26, low band pass filter 27, analog-to-digital converter 2
8, intersection zero point measuring device 29, microcomputer 30, signal tone feature detector 31, voice feature comparator 321, disease symptom determiner 322, digital speech output circuit 33,
Data storage 34, digital/analog converter 3
5, Amplifier 36, High frequency de-emphasizer 3
7, a modulator 38, a microphone and preamplifier 39, a recorder 40, a keyboard and a display device 41, and the like.

Next, details of each component of the stethoscope will be explained.

Audio/electrical converter 1: converts body sounds into electronic signals for subsequent processing, and preferably uses a condenser microphone. This is because it has sufficient acoustic sensitivity due to its relatively small volume, has a wide receiving frequency band, and has low noise characteristics.

Preamplifier 2: The signal output from the audio/electrical converter 1 must be amplified through an amplifier with high input impedance and high gain, and impedance matching must be performed for the subsequent circuit. It is preferable to use a multi-stage preamplifier, and when using the above-mentioned condenser microphone, an emitter follower is installed in the first stage.
It is preferable to use a follower type amplifier. The preamplifier is mounted as close to the audio/electrical converter 1 as possible to prevent noise from entering. Further, as for the connection between the preamplifier and the subsequent circuit, it is preferable to use a low impedance isolated conducting wire, which is connected through the inside of the sound guide tube 15. By connecting in this way, it is possible to block interference from external noise signals.

Bandpass filter 3: The macrophone signal output through the preamplifier 2 is further amplified by the signal amplifier 4, which will be described later, but before that, it is passed through the bandpass filter 3 to remove as much noise as possible. . The methods can be (a) remove low and high frequencies using a set of high-frequency bandpass filters, or (b) eliminate spikes by differentiating high-frequency signals. However, any method may be adopted.

Signal amplifier 4: Amplifies and outputs the body sound signal that has undergone some processing, and controls the audio output level by adjusting the volume, thereby adjusting the signal level to the most suitable level for the auscultator.

Function and part selection 5: Mainly composed of four sets of select switches S ₁ , S ₂ , S ₃ , S ₄ and one switch S ₅ (used for frequency selection adjustment): (a) Transmission select switch S ₁ : Select whether to connect to the transmission circuit (i.e., high frequency enhancer 7, modulator 8). When set to the on state,
That is, when connected to the transmitting circuit, signals can be supplied to a large number of auscultators, while when set to the off state, only the auscultator using the stethoscope can auscultate.

(b) Sound source selection switch _S2 : This is a switch for selecting the sound source to be auscultated, and selects either position 1 or position 2 below.

Position 1: The sound source is the stethoscope's own microphone.

Position 2: A signal received by another stethoscope is received via a receiving circuit (that is, a demodulator 10 and a de-emphasizer 11), and this is used as a sound source. In other stethoscopes, the above-mentioned switch _S1 is set to the on state.

(c) Transmission signal selection switch _S3 : A switch for selecting a signal to be transmitted via the transmission circuit.

First, in the electronic auscultation/diagnosis device of this embodiment, each stethoscope can transmit two types of signals, and the transmitted signals can be received by other auscultators or computers in the same set. .

Among these signals, one is the body sound mentioned above, and the other is the control signal for the auscultation site, which is S ₃
Controlled by a switch. Since body sounds are composite signals having a large number of frequency components, a single frequency signal different from body sounds is used to make a part signal and distinguish it from body sounds.

Position 1: The transmitted signal will be a body sound signal picked up by the microphone.

Position 2: The transmitted signal is the code signal of the part output via the _S4 select switch set.

When the switch is in position 1, the power to the part select line is cut off at the same time to save power consumption.

(d) Site selection switch set _S4 : This is a switch for selecting the above-mentioned transmission position. _S4 is a switch set that controls the start of different single frequency signals, and only one key can be pressed at the same time, and the local control signal is only used to control the operation of the electronic auscultation and diagnosis device.

(e) Transmission frequency selection switch _S5 : Provided for use with different transmission frequencies in the system, and allows selection of a desired frequency from among multiple types of frequencies.

Electrical/audio converter 6: This converts an electronic signal received by a microphone and then undergoes some processing into audio and outputs the same, and can be realized by, for example, a pair of earphones.

High frequency enhancer 7: As described above, the audio signal from the stethoscope can be monitored with an earphone and can also be output as radio waves. This high-frequency enhancer 7 improves the signal-to-noise ratio by performing high-frequency emphasis during wireless transmission in order to reduce noise interference in wireless transmission, and can be realized with a single bandpass filter and amplifier. can.

Modulator 8: The signal that has undergone high frequency emphasis,
It is converted into a transmission frequency signal by a modulation circuit and output. The frequency of wireless transmission is, for example, 78~
It is preferable to use the 90MHz frequency band that is not used by FM broadcast stations. Multiple stethoscopes, when used in the same system, allow the same receiving or transmitting frequency to be selected. Furthermore, multiple sets of systems can be used within the same time period, each employing a different frequency.

Antenna 9: for emitting and receiving FM signals. In a stethoscope, a metal conduit can be used as an antenna.

Demodulator 10: Receives a wireless electric signal transmitted from the stethoscope or computer in the set, and demodulates it into an audio frequency signal using a demodulation electric circuit.

De-emphasizer 11: De-emphasizes the signal emitted through high-frequency emphasis when receiving it, attenuates it in correspondence with the high-frequency emphasis, restores it to its original state, and improves the noise signal ratio of the signal. It is intended to improve the

Balance net circuit 12: In this embodiment, in addition to outputting body sound signals through earphones or an oscillator, it is also possible to output body sound waves by driving a recorder device. However, recorder devices have a long reaction time and cannot follow high frequency signals, and also have a reaction delay time. Therefore,
This balance net circuit 12 is provided. That is, the signals are processed in a balance circuit composed of a single bandpass filter, and then their frequency responses are matched to each other.

Recorder device 13: When the signal that has undergone balance processing is amplified by a rectifying filter, it can drive a recorder device to draw a body sound waveform.
For example, a phonocardiogram can be provided as reference material to the auscultator.

Power supply 14: can use a primary use mercury battery or other rechargeable battery;
For example, in a nickel cadmium (Ni-Cd) battery,
It is a good idea to use one charging stand so that you can always charge the stethoscope when you leave it there. The stethoscope also has a power saving design and is only connected to power once the earphone conduit is open and ready for use.

Next, the main body of the electronic auscultation/diagnosis device has the following components.

Antenna 21: Provided for receiving body sounds and auscultation site selection signals transmitted from the stethoscope, and disease symptom speech signals transmitted to the stethoscope.

Demodulator 22: Receives and demodulates a radio signal supplied from a stethoscope.

De-emphasizer 23: A device that relatively attenuates the high-frequency emphasized transmission signal of the stethoscope.

Bandpass filter 24: This is a bandpass filter whose passband is a frequency detectable by the human ear, and is designed to remove signals other than body sounds. It consists of an 18-step low-passage filter and a 3-step high-passage filter connected in series.

Fine frequency band range filter 25: Detects the frequency components included in the body sound signal, further analyzes the body sound signal in each frequency band, and analyzes the body sound pattern based on its characteristics. Understand the status of Therefore, after passing through the wide frequency band, spectrum analysis of the body sound frequency is performed using multiple sets of narrow frequency band filters. This narrow frequency bandpass filter consists of two two-step voltage controlled voltage source (VcVs) multiple pass bandpass filters connected in series. A filter can have from 5 to 32 sets.

Full-frequency rectifier 26: After the body sound signal is band-divided by each set of narrow-frequency bandpass filters,
Each of them is used to obtain one DC signal through an all-round active rectifier.

Low-passage filter 27: A DC signal obtained by passing the body sound signal through a full-frequency rectifier is further passed through a low-passage filter to remove noise signals.

Analog/digital converter 28: converts analog signals into digital signals and provides them for acceptance by the microcomputer. At the same time, the continuous signal is also transposed into discrete number form. At a certain time, the number obtained from each pass (filter set) is expressed as follows: A(t) = {X ₁ (t), X ₂ (t), ...X ₁₁ (t)} (where n is the number of paths) In the time sequence, we can collect the numbers in succession and draw a wave-shaped state, ie, a wave-shaped number set. When selecting a signal for a part, since it is a monotone signal, only one of the signals in X(t) has a non-zero value, so it can be determined as a select signal, and the computer It can be used as a basis for subsequent processing.

Intersection zero check measuring device 2: Measures the number of times the wave shape fluctuates through the reference line within a certain one-step time,
This allows us to know the true density of the basic wave shape.

Computer device 30: includes the following signal tone feature detector, signal tone feature comparator, disease symptom determiner, data recording device, digital speech output circuit, keyboard, etc.

Signal sound feature detector 31: After passing through frequency spectrum analysis and intersection/0 point measurement, it is possible to grasp the sound height level (energy amount) of body sounds and wave shape numbers such as basic wave shape density. These reference values can be seen as characteristics of body sounds. The microcomputer, combined with its software, collects and stores such numbers at fixed times, establishes body sound patterns, and uses them for subsequent processing.

Signal sound feature comparator 321: The characteristics of various pathological and normal body sounds are determined based on the knowledge and experience of experts, and are used as standards for determining the basic patterns of body sounds, such as the first heart sound and the second heart sound. The functions of this item are achieved by software, such as heart sounds, intervals between one and two heart sounds, etc.

Disease symptom determiner 322: Once a lesion occurs, the basic pattern of body sounds and the discipline (characteristics) between them will necessarily change. Achieved by software.

Digital speech output device 33: After determining the disease symptoms, it is possible to output lesion name data using the speech method. The speech data can be input into the computer by converting disease symptom names into speech signals using the microphone and preamplifier 39, and arranged into feature numbers using the filter set and software, and first stored in the computer for use.

Data recording device 34: A data storage includes speech data of lesion rules and disease names (etiology), which are stored using a storage method such as a disk machine or an optical disk machine. The main body of the electronic auscultation/diagnosis device determines the cause of the disease and diagnoses the disease symptom data based on these data.

Digital/analog converter 35 and amplifier 3
6: Digital speech materials are originally in a digital number set format, and must be changed to a voltage format through an inspection machine to reproduce the speech sounds.In other words, the discrete numbers are converted into a voltage waveform and output via an amplifier. ing.

Emphasizer 37 and modulator 38: Convert the reproduced speech sounds into radio waves, output them, and provide them to the listening collection of each stethoscope. Its specific functions are the same as the high frequency enhancer 7 and modulator 8 described above.

The microphone and preamplifier 39 are provided to input speech material and amplify the signal.

Recorder 40: Since body sounds are transmitted wirelessly,
For this purpose, it is recorded with an FM receiver and the completed recording is provided for future re-auscultation and teaching purposes, and the recorded sound is also wired and directly connected to the system.

Keyboard and display 41: Provided for key-in and display for providing letters, numbers, and symbols to the computer.

Taking all of the above into account, the electronic auscultation/diagnosis device of the present invention has one to several stethoscopes and a microcomputer device that transmits one signal. The acquired signal sound can be heard by other stethoscopes at the same time, and the microcomputer device can also process the signal sound waiting to be measured, and it can be used as a reference for comparing the signal sounds, and can be used as a reference for comparing the signal sounds. The results are generated and provided to the auscultator for reference, and the accuracy of diagnosis and its effectiveness are determined by recording, calculating, accumulating, making judgments using the system, and transmitting output from the multiplex during auscultation work. This is a new invention that has real utility value because it can add to the convenience of use.

[Brief explanation of drawings]

FIG. 1 is a perspective view of an embodiment of the electronic auscultation/diagnosis device of the present invention, FIG. 2 is a schematic diagram of the stethoscope of the present invention, FIG. 3 is a block diagram of the stethoscope of the present invention, and FIG.
The figure is a block diagram of the main body of the electronic auscultation/diagnosis device of the present invention. 1... audio/electrical converter (first conversion means),
8...Modulator (signal path), 9...Antenna (signal path), _S3 , _S4 ...Select switch (control signal generation means), 34...Data recording device (diagnosis device), 25...Details Frequency band filter (frequency component detection means), 28...analog/digital converter (frequency component detection means, determination means).

Claims (1)

[Scope of Claims] 1. A first conversion means provided in the stethoscope, which converts received sound into a signal to be measured, which is an electrical signal, and outputs the signal through a predetermined signal path; provided in the stethoscope, control signal generating means for outputting a single frequency control signal based on the operating state of a predetermined control operator and outputting this control signal via the signal path; and a diagnostic device for analyzing and recording the signal under measurement. and a frequency component detection means that is provided in the diagnostic device and detects the level of each frequency component of the input signal when the input signal is supplied through the signal path; and in the detection result of the frequency component detection means. If the input signal has a single frequency component, the input signal is determined to be the control signal, whereas if the input signal has multiple frequency components, it is determined to be the signal under test. an electronic auscultation/diagnosis device, characterized in that the diagnostic device is operated by the control signal;