JP2020081364A - Information processing device, system, information processing method, and program - Google Patents

Abstract

To improve convenience of apparatus in remote consultation, for example.SOLUTION: An information processing device 10 comprises an acquisition unit 110 and a first display control unit 130. The acquisition unit 110 acquires state information indicating the state of an electronic stethoscope 520 for auscultation of a patient. The first display control unit 130 controls a display content of a first display unit 510 which has to be viewed by a medical doctor, on the basis of the state information. The state information includes information indicating whether or not the electronic stethoscope 520 is capable of measurement, for example.SELECTED DRAWING: Figure 1

Description

The present invention relates to an information processing device, a system, an information processing method, and a program.

In medical examinations in telemedicine, doctors often make an inquiry by video call with a patient, and the diagnosis is often made based on the contents of the inquiry. Here, by using an electronic stethoscope, it is possible to perform auscultation in remote examination, and it can be expected that diagnostic accuracy is improved.

Patent Document 1 discloses a technique relating to a remote auscultation apparatus that transmits the sound of a stethoscope using a narrow band transmission path such as a telephone line. The technique of Patent Document 1 describes that an electric signal obtained by a stethoscope is output via a filter, an encoder, or the like. By doing so, auscultation sounds of different frequencies can be switched and transmitted and received.

Patent Document 2 describes a device that guides a user who uses a stethoscope to a position where the stethoscope should be applied. The doctor can diagnose the patient by reproducing and listening to the body sound. In the technique of Patent Document 2, for example, guidance is provided so that the body sound is remeasured when a predetermined condition is satisfied. By doing so, the doctor can reproduce the body sound for a plurality of times, and the diagnostic accuracy of the doctor is improved.

JP, 2002-301066, A JP, 2014-30625, A

In a remote medical interview, a doctor needs to carefully observe the patient's facial expression, complexion, and affected area. On the other hand, when conducting auscultation, the doctor needs to correctly understand which position of the patient is being auscultated. In this way, the information that the doctor particularly needs at the time of the interview is different from that at the auscultation.

One of the problems to be solved by the present invention is to improve the convenience of the device in remote diagnosis.

The invention according to claim 1 is
An acquisition unit that acquires status information indicating the status of an electronic stethoscope for auscultating a patient,
An information processing apparatus, comprising: a first display control unit that controls display contents of a first display unit that a doctor should see based on the state information.

The invention described in claim 10 is
It is a system provided with the information processing apparatus according to any one of claims 1 to 9 and the electronic stethoscope.

The invention according to claim 11 is
An acquisition step of acquiring status information indicating the status of an electronic stethoscope for auscultating a patient,
A first display control step of controlling the display content of the first display unit that the doctor should see based on the state information.

The invention according to claim 12 is
A program that causes a computer to execute each step of the information processing method according to claim 11.

It is a figure which illustrates the structure of the information processing apparatus which concerns on embodiment. 6 is a flowchart illustrating an information processing method according to an embodiment. FIG. 1 is a diagram illustrating a configuration of an information processing device and a system according to a first embodiment. FIG. 3 is a diagram illustrating a usage environment of a doctor side terminal, a patient side terminal, and a server according to the first embodiment. It is a figure which shows an example of the hardware constitutions of a doctor side terminal. It is a figure which shows an example of the hardware constitutions of a patient side terminal. It is a figure which shows an example of the hardware constitutions of a server. 6 is a flowchart illustrating the operation of the information processing apparatus according to the first embodiment. It is a figure which illustrates the display content of the 1st display part in inquiry mode. It is a figure which shows the 1st example of the display content of the 1st display part in auscultation mode. It is a figure which shows the 2nd example of the display content of the 1st display part in auscultation mode. It is a figure which illustrates the map which appoints or displays an auscultation position. It is a figure which shows the 3rd example of the display content of the 1st display part in auscultation mode. FIG. 9 is a diagram illustrating the configurations of an information processing device and a system according to a second embodiment. FIG. 9 is a diagram illustrating the configurations of an information processing device and a system according to a third embodiment. It is a figure which illustrates the display content of the 2nd display part in inquiry mode. It is a figure which illustrates the display content of the 2nd display part in auscultation mode. 9 is a flowchart illustrating a method of using the information processing apparatus according to the third embodiment.

Embodiments of the present invention will be described below with reference to the drawings. In all the drawings, the same reference numerals are given to the same components, and the description thereof will be omitted as appropriate.

In the following description, each component of the information processing device 10 shows a block of a functional unit rather than a configuration of a hardware unit unless otherwise specified. Each component of the information processing apparatus 10 includes a CPU of any computer, a memory, a program loaded in the memory, a storage medium such as a hard disk for storing the program, and an optional hardware and software such as a network connection interface. It is realized by the combination of. Then, there are various modified examples of the realizing method and the apparatus.

(Embodiment)
FIG. 1 is a diagram illustrating a configuration of an information processing device 10 according to the embodiment. The information processing device 10 according to the present embodiment includes an acquisition unit 110 and a first display control unit 130. The acquisition unit 110 acquires status information indicating the status of the electronic stethoscope 520 for auscultating a patient. The 1st display control part 130 controls the display content of the 1st display part 510 which a doctor should see based on state information.

The system 20 according to the present embodiment includes the information processing device 10 and an electronic stethoscope 520. The system 20 according to the present embodiment is a system used for remote diagnosis.

The electronic stethoscope 520 is used for auscultation of a patient. The electronic sound stethoscope 520 detects the body sound of the patient and converts it into an electric signal. Then, the sound data indicating the sound wave waveform of the body sound is transmitted to the doctor side terminal through the communication network. The doctor can confirm the body sound of the patient by reproducing the sound data on the doctor terminal.

Also, a camera is connected to the terminal used on the patient side, so that the doctor can check the condition of the patient. It is preferable that the doctor, for example, carefully observe the patient's face and affected area at the time of interview. On the other hand, at the time of auscultation, it is preferable that the doctor correctly grasps the position of the electronic stethoscope 520 on the patient.

According to the information processing device 10 according to the present embodiment, the first display control unit 130 switches the display content of the first display unit 510 to be examined by the doctor based on the state information of the electronic stethoscope 520. For example, when the electronic stethoscope 520 is in a state capable of detecting sound, the display mode of the first display unit 510 is an auscultation mode suitable for auscultation, and when the electronic stethoscope 520 is not in a state capable of detecting sound, the first The display mode of the display unit 510 is the inquiry mode suitable for the inquiry.

FIG. 2 is a flowchart illustrating the information processing method according to the embodiment. The information processing method includes an acquisition step S110 and a first display control step S130. In acquisition step S110, status information indicating the status of the electronic stethoscope 520 for auscultating a patient is acquired. In 1st display control step S130, the display content of the 1st display part 510 which a doctor should see is controlled based on state information. The information processing method according to the present embodiment can be realized by the information processing device 10.

As described above, according to the present embodiment, the first display control unit 130 controls the display content of the first display unit 510 that the doctor should see based on the state information. Therefore, the device operation in the remote examination is simplified and the convenience is improved. In addition, since the doctor can easily obtain appropriate information, the diagnostic accuracy is improved.

(Example 1)
FIG. 3 is a diagram illustrating the configurations of the information processing device 10 and the system 20 according to the first embodiment. The information processing device 10 and the system 20 according to the first embodiment have the configurations of the information processing device 10 and the system 20 according to the embodiment, respectively.

FIG. 4 is a diagram illustrating a usage environment of the doctor side terminal 51, the patient side terminal 52, and the server 55 according to the first embodiment. The doctor side terminal 51, the patient side terminal 52, and the server 55 are connected to each other via the communication network 500. For example, a remote examination is realized by the cooperation of the doctor side terminal 51, the patient side terminal 52, and the server 55.

The information processing device 10 is realized by any one of the doctor side terminal 51, the patient side terminal 52, and the server 55. That is, at least one of the doctor-side terminal 51, the patient-side terminal 52, and the server 55 includes the acquisition unit 110, which is a functional configuration unit of the information processing apparatus 10, and the first display control unit 130 as functional configuration units thereof. .. At least one of acquisition of information by the acquisition unit 110 and control of the electronic stethoscope 520 by the first display control unit 130 may be performed via the communication network 500. The remote examination may be realized by the doctor side terminal 51 and the patient side terminal 52 without using the server 55.

Each functional component of the doctor side terminal 51, the patient side terminal 52, and the server 55 is, for example, a combination of hardware and software that realizes each functional component (for example, a combination of an electronic circuit and a program for controlling it). ) Is realized.

FIG. 5 is a diagram showing an example of the hardware configuration of the doctor side terminal 51. The doctor side terminal 51 is realized using the computer 1000. The computer 1000 is an arbitrary computer. For example, the computer 1000 is an SoC (System On Chip), a personal computer (PC), a server machine, a tablet terminal, a smartphone, or the like. The computer 1000 may be a dedicated computer designed to realize the doctor-side terminal 51 or a general-purpose computer.

The computer 1000 has a bus 1020, a processor 1040, a memory 1060, a storage device 1080, an input/output interface 1100, and a network interface 1120. The bus 1020 is a data transmission path for the processor 1040, the memory 1060, the storage device 1080, the input/output interface 1100, and the network interface 1120 to exchange data with each other. However, the method of connecting the processors 1040 and the like to each other is not limited to bus connection. The processor 1040 is various processors such as a CPU (Central Processing Unit), a GPU (Graphics Processing Unit), or an FPGA (Field-Programmable Gate Array). The memory 1060 is a main storage device realized by using a RAM (Random Access Memory) or the like. The storage device 1080 is an auxiliary storage device realized by using a hard disk, an SSD (Solid State Drive), a memory card, a ROM (Read Only Memory), or the like.

The input/output interface 1100 is an interface for connecting the computer 1000 and an input/output device. For example, the first display unit 510, the camera 512, the sound output unit 513, the microphone 514, and the input device 516 are connected to the input/output interface 1100. The input device 516 is, for example, a keyboard or a mouse. Note that the input/output interface 1100 may be connected with a touch panel that also serves as the first display unit 510 and the input device 516.

The network interface 1120 is an interface for connecting the computer 1000 to the communication network 500. The communication network 500 is, for example, a LAN (Local Area Network) or a WAN (Wide Area Network). The method by which the network interface 1120 connects to the network may be a wireless connection or a wired connection.

The storage device 1080 stores a program module that implements each functional component of the doctor side terminal 51. The processor 1040 realizes the function corresponding to each program module by reading each of these program modules into the memory 1060 and executing them.

FIG. 6 is a diagram showing an example of the hardware configuration of the patient-side terminal 52. The patient side terminal 52 is realized using the computer 2000. The computer 2000 is an arbitrary computer. This computer 2000 has a bus 2020, a processor 2040, a memory 2060, a storage device 2080, an input/output interface 2100, and a network interface 2120. These are the same as the bus 1020, the processor 1040, the memory 1060, the storage device 1080, the input/output interface 1100, and the network interface 1120 shown in FIG. However, the electronic stethoscope 520, the second display unit 521, the camera 522, the sound output unit 523, the microphone 524, and the input device 526 are connected to the input/output interface 2100. Note that the input/output interface 2100 may be connected to a touch panel that also serves as the second display unit 521 and the input device 526.

FIG. 7 is a diagram illustrating an example of the hardware configuration of the server 55. The server 55 is realized using the computer 5000. The calculator 5000 is an arbitrary calculator. This computer 5000 has a bus 5020, a processor 5040, a memory 5060, a storage device 5080, an input/output interface 5100, and a network interface 5120. These are the same as the bus 1020, the processor 1040, the memory 1060, the storage device 1080, the input/output interface 1100, and the network interface 1120 shown in FIG. However, an output device 551 such as a display and a speaker and an input device 553 such as a microphone, a keyboard and a mouse are connected to the input/output interface 5100.

The doctor-side terminal 51 includes a first display unit 510, a camera 512, a sound output unit 513, and a microphone 514. The doctor side terminal 51 is mainly used by a doctor. The first display unit 510 is a display that the doctor should see. The camera 512 is a photographing device such as a web camera for photographing the state of the doctor, especially the doctor's face. The sound output unit 513 is a device that outputs, as a sound, the body sound acquired by the electronic stethoscope 520, the voice of the patient acquired by the microphone 524 of the patient-side terminal 52, and is, for example, a speaker, headphones, or earphones. .. The microphone 514 acquires the voice of the doctor. The doctor can use the sound output unit 513 and the microphone 514 to talk with the patient and the assistant using the patient-side terminal 52.

The patient-side terminal 52 includes an electronic stethoscope 520, a second display unit 521, a camera 522, a sound output unit 523, and a microphone 524. The patient side terminal 52 is mainly used by a patient or an assistant. The assistant is a person who assists the medical examination, and examples thereof include a caregiver, a nurse, and other doctors. The electronic stethoscope 520 is a stethoscope for acquiring the body sound of the patient. The second display unit 521 is a display that the patient should see. The camera 522 is a photographing device such as a web camera that photographs the state of the patient. The sound output unit 523 is a device that outputs the voice of the doctor or the like acquired by the microphone 514 of the doctor side terminal 51 as a sound, and is, for example, a speaker, headphones, or earphones. The microphone 524 acquires a patient's voice or the like. The patient and the assistant can talk with the doctor using the doctor side terminal 51 by using the sound output unit 523 and the microphone 524.

The electronic stethoscope 520 will be described in detail below. The electronic stethoscope 520 detects the body sound of the patient during auscultation. The electronic stethoscope 520 includes a sensor that converts body sound into an electric signal. Then, the electronic stethoscope 520 outputs sound data indicating the body sound. The sensor is, for example, a microphone or a vibration sensor. The microphone converts air vibrations caused by body sounds into electric signals. The signal level value of this electric signal indicates the sound pressure of the vibration of the air. On the other hand, the vibration sensor converts the vibration of the medium (for example, the body surface of the subject) caused by the body sound into an electric signal. The signal level value of this electric signal indicates the vibration displacement of the medium. For example, when the vibration sensor includes a diaphragm, the vibration of the medium is transmitted to the diaphragm and the vibration of the diaphragm is converted into an electric signal. The electric signal may be an analog signal or a digital signal. In addition to the sensor, the electronic stethoscope 520 is configured to include a circuit that processes an electric signal and the like. Examples of circuits that process electric signals include A/D conversion circuits and filter circuits. However, the processing of the electric signal may be performed by the information processing device 10.

The acquisition unit 110 acquires sound data. The sound data is data indicating an electric signal, and is data indicating the signal level value of the electric signal obtained by the electronic stethoscope 520 in time series. That is, the sound data represents the waveform of a sound wave.

The electronic stethoscope 520 further outputs status information, and the acquisition unit 110 acquires the status information. The state information includes information indicating whether or not the electronic stethoscope 520 is in a measurable state.

An example of how to use the electronic stethoscope 520 will be described. A user of the electronic stethoscope 520 (for example, a patient or an assistant) turns on the electronic stethoscope 520 before measuring a body sound. By doing so, the electronic stethoscope 520 enters a standby state for measurement. Then, the user applies the detection unit (for example, a chest piece) of the electronic stethoscope 520 to the patient's body. The detection unit of the electronic stethoscope 520 is equipped with a pressure sensor, and can detect that the detection unit has been applied to the patient's body. The pressure sensor constitutes a measurement switch, and the body sound is measured by the electronic stethoscope 520 while the pressure sensor detects pressure. The measurement stops when the detector moves away from the patient's body. Further, when the user turns off the power of the electronic stethoscope 520, the operation of the electronic stethoscope 520 ends.

The power can be switched on and off by a power switch provided on the main body of the electronic stethoscope 520, or by a predetermined switching operation of the patient terminal 52 on the computer 2000. Further, a switch that can be operated separately from the pressure sensor may be further provided in the electronic stethoscope 520 as a measurement switch.

The state information includes, for example, at least one of information indicating whether the electronic stethoscope 520 is powered on or off and information indicating whether the electronic stethoscope 520 is measuring. Power on/off can be switched by the above-mentioned power switch, for example. Further, whether or not the electronic stethoscope 520 is measuring is switched by, for example, the above-described measurement switch.

For example, the first display control unit 130 determines that auscultation is in progress when the electronic stethoscope 520 is under measurement, and sets the display mode to auscultation mode. However, the first display control unit 130 may determine that the auscultation is being prepared when the power of the electronic stethoscope 520 is turned on, and set the display mode to the auscultation mode. In addition, the first display control unit 130 determines that the electronic stethoscope 520 is not under auscultation when the measurement is stopped, and sets the display mode to the inquiry mode. However, the first display control unit 130 may determine that the auscultation has ended when the power of the electronic stethoscope 520 is turned off, and set the display mode to the inquiry mode. Note that each mode will be described later in detail.

The status information may include, for example, a digital signal indicating the status of the electronic stethoscope 520. For example, when the digital signal is one of low level and high level, it indicates that the electronic stethoscope 520 is in a measurable state, and when the digital signal is the other level, it indicates that the electronic stethoscope 520 is not in a measurable state. However, in addition to or instead of the digital signal, the state information may include a signal or a command output when the state of the electronic stethoscope 520 is switched. This signal or command is, for example, information indicating that the electronic stethoscope 520 is in a measurable state or information indicating that the electronic stethoscope 520 is not in a measurable state. The first display control unit 130 can determine that the state up to that time continues unless the acquisition unit 110 acquires a new signal or command. The measurable state is at least one of a state in which the electronic stethoscope 520 is measuring and a state in which the electronic stethoscope 520 is powered on.

The sound data may also serve as the status information. For example, when the waveform of the sound data in the information processing device 10 includes a specific pattern, the first display control unit 130 can determine that the electronic stethoscope 520 is measuring. The specific pattern is, for example, a pattern corresponding to breath sounds and heart sounds. Whether or not a specific pattern is included in the waveform of the sound data is determined by, for example, pattern matching with a reference pattern stored in advance in a storage unit or the like. The storage unit is at least one of the storage device 1080, the storage device 2080, and the storage device 5080.

FIG. 8 is a flowchart illustrating the operation of the information processing device 10 according to the first embodiment. The first display control unit 130 switches between the inquiry mode and the auscultation mode based on the state information. The first display control step S130 includes steps S131, S133, and S134. This will be described in detail below.

The acquisition unit 110 always receives the status information from the electronic stethoscope 520 (acquisition step S110). Then, in step S131, the first display control unit 130 determines whether or not the auscultation or the auscultation preparation is in progress, as described above, based on the state information. This determination is made at predetermined intervals (eg, every second). Next, when it is determined that the auscultation or the auscultation preparation is being performed in step S131 (Yes in step S131), the first display control unit 130 sets the display of the first display unit 510 to the auscultation mode (step S133). On the other hand, when it is determined in step S131 that the auscultation or the preparation for auscultation is not performed (No in step S131), the first display control unit 130 sets the display of the first display unit 510 to the inquiry mode (step S134). After step S133 and step S134, the first display control unit 130 performs step S135. In step S135, it is determined whether or not the medical examination continues. Specifically, for example, when at least one of the doctor side terminal 51 and the patient side terminal 52 is operated to be terminated, it is determined that the medical examination is completed, and in other cases, it is determined that the medical examination is continued. It When the medical examination continues (No in step S135), the acceptance of the state information (step S110) and the determination of the electronic stethoscope 520 (step S131) are repeated. By doing so, the display content of the first display unit 510 can be appropriately switched between the interview and the auscultation. On the other hand, when the medical examination ends (Yes in step S135), the process of the information processing device 10 ends.

FIG. 9 is a diagram exemplifying the display contents of the first display unit 510 in the inquiry mode. In the example of the figure, the image of the face of the patient is displayed large on the first display unit 510. This image is the one obtained by camera 522, ie camera 522 is zoomed towards the patient's face. In the inquiry mode, the camera 522 may be zoomed toward the affected part of the patient, and the image of the affected part of the patient may be displayed large on the first display unit 510. With such display contents of the first display unit 510, the doctor can confirm the complexion and facial expression of the patient, the condition of the affected part, etc., and can assist the diagnosis. Further, in the example of the figure, the image of the doctor's face is also displayed on the first display unit 510. This image is an image captured by the camera 512 and is also displayed on the second display unit 521 of the patient-side terminal 52 at the same time. By displaying the image of the doctor's face on the first display unit 510, the doctor can confirm the image acquired by the camera 512 and displayed on the patient side terminal 52.

FIG. 10: is a figure which shows the 1st example of the display content of the 1st display part 510 in auscultation mode. In the example of this figure, an image including the entire chest of the patient is displayed instead of the image of a large size of the patient's face. Further, as in FIG. 9, the image of the doctor's face is also displayed on the first display unit 510. In addition, as described above, the acquisition unit 110 further acquires sound data indicating body sounds obtained by auscultation. Then, the acquired sound data is output from the sound output unit 513. By displaying the image including the entire chest of the patient on the first display unit 510, the doctor can perform auscultation while accurately ascertaining which position of the body of the patient biological sound is acquired. Accurate diagnosis can be performed. In addition, the user of the electronic stethoscope 520 can be advised on the position of auscultation, etc., if necessary.

As described above, the display content of the first display unit 510 includes the image including the patient at least temporarily. Here, the first display control unit 130 controls at least one of the angle of view and the direction of the camera 522 for acquiring an image based on the state information acquired by the acquisition unit 110. Specifically, at least one of the angle of view and the direction of the camera 522 is controlled by a control signal from the first display controller 130. The first display control unit 130 performs control so that it is easy to see the patient's face or affected area in the inquiry mode and it is easy to understand which position of the patient's body is being auscultated in the auscultation mode. That is, the first display control unit 130 makes the angle of view of the camera 522 in the auscultation mode wider than the angle of view of the camera 522 in the inquiry mode. Further, the first display control unit 130 directs the camera 522 toward the patient's body in the auscultation mode. By controlling at least one of the angle of view and the direction of the camera 522 in this way, it is possible to switch images even when only one camera 522 is used.

The control signal is a signal indicating the angle of view and the direction of the camera 522. The information indicating the angle of view and the direction in each mode is stored in advance in a storage unit (for example, one of the storage device 1080, the storage device 2080, and the storage device 5080) accessible from the first display control unit 130. The first display control unit 130 can read it and use it for control. Further, the user of the patient side terminal 52 or the doctor side terminal 51 can set the angle of view and the direction in each mode prior to the medical examination. Then, information indicating the set angle of view and direction is held in the storage unit.

The inquiry mode and the auscultation mode can be switched based on the state information as described above, or can be switched by the user performing a switching operation on each terminal.

In the example of FIG. 3, the information processing device 10 further includes an analysis unit 150. The analysis unit 150 analyzes the sound data acquired by the acquisition unit 110. Then, the first display control unit 130 controls the timing at which at least one of the sound data acquired from the electronic stethoscope 520 and the analysis result of the sound data is displayed on the first display unit 510 based on the state information. The first display control unit 130 may cause the first display unit 510 to display at least one of the sound data and the analysis result of the sound data when the display of the first display unit 510 is switched to the auscultation mode. Further, the first display control unit 130 displays at least one of the sound data and the analysis result of the sound data at a time point when a predetermined time elapses after the display of the first display unit 510 is switched to the auscultation mode, for example. It may be displayed on the 1 display unit 510.

FIG. 11 is a diagram showing a second example of the display contents of the first display section 510 in the auscultation mode. In the example of this figure, the display content of the first display unit 510 includes an image of the patient being auscultated and an image of the doctor's face, as well as a map indicating the auscultation position and the analysis result of the sound data.

FIG. 12 is a diagram illustrating a map for designating or displaying an auscultation position. For example, the user of the electronic stethoscope 520 inputs the position to which the electronic stethoscope 520 is attached to the patient-side terminal 52 prior to the auscultation of each position. For example, on the second display unit 521 of the patient-side terminal 52, a diagram (map) showing the shape of the body as shown in the figure and a mark indicating a candidate position for auscultation are also shown. Then, the user of the patient side terminal 52 selects the position of the target to be auscultated by using the input device 526 such as a mouse, and inputs it to the patient side terminal 52. The patient side terminal 52 receives the input. The input position is displayed in the map displayed on the second display unit 521 so as to be distinguishable by, for example, color. By checking the map showing such an auscultation position and the image of the patient undergoing auscultation, the doctor can accurately grasp the auscultation position. Further, information indicating the position is associated with the sound data obtained by the electronic stethoscope 520 and used for analysis and the like.

In the example of FIG. 11, the first display unit 510 displays the respiratory rate and the intensity of each sound component as the analysis result of the sound data. The analysis unit 150 calculates the breathing cycle based on, for example, the magnitude of the amplitude of the acquired sound data, and calculates the number of breaths per minute.

Further, the analysis unit 150 derives the intensity of each sound component by performing pattern matching on the waveform of the acquired sound data, for example. Examples of sound components include normal alveolar breath sounds, snoring sounds, whistling sounds, crepit sounds, and blistering sounds. A plurality of reference waveform data for pattern matching is stored in advance in a storage unit (eg, storage device 1080, storage device 2080, or storage device 5080) accessible from the analysis unit 150, and the analysis unit 150 reads it. get. Each reference waveform data is associated with each sound component. Then, the analysis unit 150 performs pattern matching between the sound data acquired by the acquisition unit 110 and each reference waveform data, and calculates the degree of similarity with each reference waveform data. Then, the calculated similarity is used as the strength of each component.

However, the analysis unit 150 may derive the intensity of each sound component by the following method. A plurality of reference information is held in advance in the storage unit accessible from the analysis unit 150. Each reference information is associated with a specific sound component, and is information including the generation timing and frequency characteristic of the sound component. For example, the twisting sound appears in a relatively high frequency band in the inspiratory phase of breathing. On the other hand, the bubbly sound appears in a relatively low frequency band in both the inspiration phase and the expiration phase. Therefore, the intensity of each sound component can be derived more accurately by using the reference information including the parameter for each generation time and each frequency characteristic.

The reference information is, for example, as a parameter, an expiratory phase value in a high frequency band (750 Hz to 4 kHz), an inspiratory phase value in a high frequency band, an expiratory phase value in a low frequency band (0 Hz to 750 Hz), and an inspiratory phase value in a low frequency band. Includes four numbers. Here, each numerical value corresponds to the appearance probability of a sound component. Then, the analysis unit 150 calculates the power of the expiratory phase in the high frequency band, the power of the inspiratory phase in the high frequency band, the power of the expiratory phase in the low frequency band, and the power of the inspiratory phase in the low frequency band based on the sound data. .. It can be said that the closer the balance of these powers is to the balance of the parameters of the reference information, the higher the probability of including the sound component. Therefore, the analysis unit 150 calculates the likelihood (degree of coincidence) using the parameter included in the reference information and the calculated power, and sets the calculated likelihood as the strength of each component. The analysis method of the analysis unit 150 is not limited to these examples.

Then, the first display control unit 130 causes the first display unit 510 to display the analysis result of the sound data at the timing as described above. The doctor can make a diagnosis by referring to the analysis result displayed on the first display unit 510.

The information processing device 10 according to the present embodiment does not necessarily have to include the analysis unit 150.

In the example of FIG. 3, the information processing device 10 further includes a detection unit 160. The detection unit 160 detects an abnormality of the patient based on the sound data acquired by the electronic stethoscope 520. Specifically, the detection unit 160 can detect the abnormality of the patient based on the analysis result of the analysis unit 150. That is, when the intensity of each component derived by the analysis unit 150 exceeds a predetermined reference value, the detection unit 160 determines that the patient has an abnormality (that is, detects an abnormality). The reference value is independently set for each component, and is stored in a storage unit (for example, storage device 1080, storage device 2080, or storage device 5080) accessible from the detection unit 160. In addition, the detection unit 160 determines that the patient has an abnormality (that is, detects an abnormality) when the respiratory rate derived by the analysis unit 150 exceeds a predetermined number of times.

FIG. 13 is a diagram showing a third example of display contents of the first display section 510 in the auscultation mode. This figure shows the display contents when the detection unit 160 detects an abnormality. When the detection unit 160 detects an abnormality, the first display control unit 130 causes the first display unit 510 to display that the abnormality has been detected.

The information processing device 10 according to the present embodiment does not necessarily have to include the detection unit 160.

Further, in the inquiry mode, the past auscultation result, diagnosis result, and the like may be further displayed on the first display unit 510 according to the operation on the doctor side terminal 51.

As described above, according to the present embodiment, the first display control unit 130 controls the display content of the first display unit 510 to be viewed by the doctor based on the state information, as in the embodiment. Therefore, the device operation in the remote examination is simplified and the convenience is improved. In addition, since the doctor can easily obtain appropriate information, the diagnostic accuracy is improved.

(Example 2)
FIG. 14 is a diagram illustrating the configurations of the information processing device 10 and the system 20 according to the second embodiment. The information processing apparatus 10 and the system 20 according to the present embodiment are the same as the information processing apparatus 10 and the system 20 according to the first embodiment, respectively, except for the points described below.

In the present embodiment, the display content of the first display unit 510 includes an image including the patient at least temporarily. Then, the acquisition unit 110 can acquire images including the patient from the plurality of cameras 522. That is, a plurality of cameras 522 are connected to the input/output interface 2100 of the computer 2000. Then, the first display control unit 130 selects the camera 522 for acquiring the image to be displayed on the first display unit 510 from the plurality of cameras 522 based on the state information. This will be described in detail below.

The display content of the first display unit 510 in the inquiry mode according to this embodiment is illustrated in FIG. The display contents of the first display unit 510 in the auscultation mode according to this embodiment are illustrated in FIGS. 10, 11, and 13.

In the present embodiment, the plurality of cameras 522 are provided so as to photograph different areas. For example, the first camera 522, which is one of the plurality of cameras 522, is installed so as to take a larger image of the patient's face than the other cameras 522. In addition, the second camera 522, which is one of the plurality of cameras 522, may be installed so as to take a larger image of the affected area of the patient than the other cameras 522. In the inquiry mode, the images displayed by the cameras 522 of the first camera 522 and the second camera 522 are included in the display content of the first display unit 510. When the plurality of cameras 522 include both the first camera 522 and the second camera 522, the images of these cameras 522 can be switched according to the operation on the doctor side terminal 51 in the inquiry mode. However, both the image captured by the first camera 522 and the image captured by the second camera 522 may be displayed simultaneously.

On the other hand, the plurality of cameras 522 includes a third camera 522 installed for photographing the entire chest of the patient. Then, in the auscultation mode, the display content of the first display unit 510 includes the image acquired by the third camera 522.

Similar to the first embodiment, the first display control unit 130 switches between the inquiry mode and the auscultation mode based on the state information. As a result, among the images obtained by the plurality of cameras 522, the image displayed on the first display unit 510 is switched based on the state information. Therefore, the images can be switched instantly.

As described above, according to the present embodiment, the first display control unit 130 controls the display content of the first display unit 510 to be viewed by the doctor based on the state information, as in the embodiment. Therefore, the device operation in the remote examination is simplified and the convenience is improved. In addition, since the doctor can easily obtain appropriate information, the diagnostic accuracy is improved.

(Example 3)
FIG. 15 is a diagram illustrating the configurations of the information processing device 10 and the system 20 according to the third embodiment. The information processing device 10 and the system 20 according to the present embodiment are the same as the information processing device 10 and the system 20 according to at least one of the first and second embodiments, respectively, except that the second display control unit 170 is further included. is there. The 2nd display control part 170 controls the display content of the 2nd display part 521 which a patient should see based on state information. This will be described in detail below.

FIG. 16: is a figure which illustrates the display content of the 2nd display part 521 in inquiry mode. In the example of this figure, the image of the doctor's face acquired by the camera 512 of the doctor-side terminal 51 is displayed large on the second display unit 521. With such display contents of the second display unit 521, the patient and the assistant can safely consult the doctor while looking at the facial expression of the doctor. Further, in the example of this figure, the image of the patient's face is also displayed on the second display unit 521. This image is an image captured by the camera 522 and is also displayed on the first display unit 510 of the doctor side terminal 51 at the same time. By displaying the image of the patient's face on the electronic stethoscope 520, the patient and the assistant can confirm the image captured by the camera 522 and displayed on the doctor-side terminal 51.

FIG. 17: is a figure which illustrates the display content of the 2nd display part 521 in auscultation mode. In the example of this figure, in addition to the image of the doctor's face, the display content of the second display unit 521 shows the image of the patient simultaneously displayed on the first display unit 510, the analysis result of the sound data, and the auscultation position. Contains maps.

The second display control unit 170 switches between the inquiry mode and the auscultation mode on the second display unit 521 based on the state information, in the same manner as the first display control unit 130 switches the display mode of the first display unit 510. To do. For example, the switching between the inquiry mode and the auscultation mode on the second display unit 521 can be performed at the same time as the switching between the inquiry mode and the auscultation mode on the first display unit 510.

In addition, the second display control unit 170 may control the timing of displaying the guide information regarding the use of the electronic stethoscope 520 on the second display unit 521 based on the state information. The second display unit 521 can start displaying the guide information immediately after switching the display content of the second display unit 521 to the auscultation mode, for example. The guide information is displayed on the second display unit 521 together with the images obtained by the cameras 512 and 522 as described above.

FIG. 18 is a flowchart illustrating a method of using the information processing device 10 according to the third embodiment. The operation of the information processing device 10 will be described with reference to this figure. When the inquiry mode is switched to the auscultation mode, a map as shown in FIG. 12 is displayed on the first display unit 510 of the doctor side terminal 51. Then, the doctor designates the position where the patient should auscultate on the map (step S210). When the doctor side terminal 51 accepts the designation, a map as shown in FIG. 12 is displayed on the second display unit 521 of the patient side terminal 52, and the position designated by the doctor side terminal 51 is clearly indicated on the map ( Step S220). The position is specified by, for example, changing the color of the mark at the specified position on the map.

The user of the electronic stethoscope 520 confirms the second display unit 521 and stethoscopes the designated position with the electronic stethoscope 520 (step S230). Then, when the auscultation of the position is completed, the user inputs the completion to the patient side terminal 52 (step S240). Then, the fact that the auscultation at the designated position is completed is displayed on the first display unit 510 of the doctor side terminal 51 (step S250). By repeating steps S210 to S250 as necessary, auscultation can be easily performed. In addition, a smooth medical examination is performed while appropriately communicating between the doctor and the patient. Further, the sound data obtained by the electronic stethoscope 520 is associated with the information indicating the designated position at that time. By doing so, data management and analysis becomes easy.

The maps and the like displayed on the first display section 510 and the second display section 521 in steps S210 to S250 correspond to the guide information. Here, the guide information displayed on the second display unit 521 can be based on, for example, the real-time guidance operation on the doctor side terminal 51 as described above. Further, the guide information may include a method of operating the electronic stethoscope 520. In that case, it is particularly preferable that the second display unit 521 display the guide information based on the state information when the power of the electronic stethoscope 520 is turned on.

As described above, according to the present embodiment, similarly to the embodiment, the first display control unit 130 controls the display content of the first display unit 510 that the doctor should see based on the state information. Therefore, the device operation in the remote examination is simplified and the convenience is improved. In addition, since the doctor can easily obtain appropriate information, the diagnostic accuracy is improved.

In addition, according to the present embodiment, the second display control unit 170 controls the display content of the second display unit 521 that the patient should see based on the state information. Therefore, the remote examination can be performed more smoothly.

Although the embodiments of the present invention have been described above with reference to the drawings, these are merely examples of the present invention, and various configurations other than the above may be adopted. For example, in the sequence diagrams and flowcharts used in the above description, a plurality of processes (processes) are described in order, but the execution order of the processes executed in each embodiment is not limited to the described order. In each embodiment, the order of the illustrated steps can be changed within a range that does not hinder the contents. Further, the above-described respective embodiments can be combined within a range in which the contents do not conflict with each other.

Hereinafter, an example of the reference mode will be additionally described.
1-1. An acquisition unit that acquires status information indicating the status of an electronic stethoscope for auscultating a patient,
An information processing apparatus, comprising: a first display control unit that controls display contents of a first display unit that a doctor should see based on the state information.
1-2. 1-1. In the information processing device described in
The display content of the first display unit includes an image including the patient at least temporarily,
The first display control unit is an information processing device that controls at least one of an angle of view and a direction of a camera for acquiring the image, based on the state information.
1-3. 1-1. In the information processing device described in
The display content of the first display unit includes an image including the patient at least temporarily,
The said 1st display control part is an information processing apparatus which selects the said camera for acquiring the said image from several cameras based on the said state information.
1-4. 1-1. To 1-3. In the information processing device according to any one of
The first display control unit is an information processing apparatus that controls a timing of displaying at least one of sound data acquired from the electronic stethoscope and an analysis result of the sound data on the first display unit based on the state information.
1-5. 1-1. To 1-4. In the information processing device according to any one of
The information processing device, wherein the state information includes information indicating whether or not the electronic stethoscope is in a measurable state.
1-6. 1-5. In the information processing device described in
The state information includes an information processing device including at least one of information indicating whether the electronic stethoscope is powered on or off and information indicating whether the electronic stethoscope is measuring. ..
1-7. 1-1. To 1-6. In the information processing device according to any one of
The information processing apparatus further comprising a second display control unit that controls the display content of the second display unit to be viewed by the patient based on the state information.
1-8. 1-7. In the information processing device described in
The said 2nd display control part is an information processing apparatus which controls the timing which displays the guide information regarding the use of the said electronic stethoscope on the said 2nd display part based on the said state information.
1-9. 1-1. To 1-8. In the information processing device according to any one of
Based on the sound data acquired by the electronic stethoscope, further comprising a detection unit for detecting an abnormality of the patient,
The said 1st display control part is an information processing apparatus which makes the said 1st display part display that the said abnormality was detected, when the said detection part detects the said abnormality.
2-1. 1-1. To 1-9. A system including the information processing apparatus according to any one of claims 1 to 5 and the electronic stethoscope.
3-1. An acquisition step of acquiring status information indicating the status of an electronic stethoscope for auscultating a patient,
A first display control step of controlling the display content of the first display section which the doctor should see based on the state information.
3-2. 3-1. In the information processing method described in
The display content of the first display unit includes an image including the patient at least temporarily,
In the first display control step, an information processing method for controlling at least one of an angle of view and a direction of a camera for acquiring the image based on the state information.
3-3. 3-1. In the information processing method described in
The display content of the first display unit includes an image including the patient at least temporarily,
In the first display control step, an information processing method of selecting the camera for acquiring the image from a plurality of cameras based on the state information.
3-4. 3-1. To 3-3. In the information processing method described in any one of
In the first display control step, an information processing method for controlling timing of displaying at least one of sound data acquired from the electronic stethoscope and an analysis result of the sound data on the first display unit based on the state information.
3-5. 3-1. To 3-4. In the information processing method described in any one of
The information processing method, wherein the state information includes information indicating whether or not the electronic stethoscope is in a measurable state.
3-6. 3-5. In the information processing method described in
The status information includes an information processing method including at least one of information indicating whether the electronic stethoscope is powered on or off and information indicating whether the electronic stethoscope is measuring. ..
3-7. 3-1. To 3-6. In the information processing method described in any one of
The information processing method further comprising a second display control step of controlling the display content of the second display unit to be viewed by the patient based on the state information.
3-8. 3-7. In the information processing method described in
In the second display control step, an information processing method of controlling a timing at which guide information regarding the use of the electronic stethoscope is displayed on the second display unit based on the state information.
3-9. 3-1. To 3-8. In the information processing method described in any one of
Further comprising a detection step of detecting an abnormality of the patient based on the sound data acquired by the electronic stethoscope,
In the first display control step, when the abnormality is detected in the detection step, an information processing method of displaying a message indicating that the abnormality is detected on the first display unit.
4-1. 3-1. To 3-9. A program that causes a computer to execute each step of the information processing method described in any one of 1.

10 information processing device 20 system 51 doctor side terminal 52 patient side terminal 55 server 110 acquisition unit 130 first display control unit 150 analysis unit 160 detection unit 170 second display control unit 500 communication network 510 first display unit 512, 522 camera 513 , 523 Sound output unit 514, 524 Microphone 516, 526, 553 Input device 520 Electronic stethoscope 521 Second display unit 551 Output device 1000, 2000, 5000 Calculator

Claims (12)

An acquisition unit that acquires status information indicating the status of an electronic stethoscope for auscultating a patient,
An information processing apparatus, comprising: a first display control unit that controls display contents of a first display unit that a doctor should see based on the state information. The information processing apparatus according to claim 1,
The display content of the first display unit includes an image including the patient at least temporarily,
The first display control unit is an information processing device that controls at least one of an angle of view and a direction of a camera for acquiring the image, based on the state information. The information processing apparatus according to claim 1,
The display content of the first display unit includes an image including the patient at least temporarily,
The said 1st display control part is an information processing apparatus which selects the said camera for acquiring the said image from several cameras based on the said state information. The information processing apparatus according to any one of claims 1 to 3,
The first display control unit is an information processing device that controls a timing of displaying at least one of sound data acquired from the electronic stethoscope and an analysis result of the sound data on the first display unit based on the state information. The information processing apparatus according to any one of claims 1 to 4,
The information processing device, wherein the state information includes information indicating whether or not the electronic stethoscope is in a measurable state. The information processing apparatus according to claim 5,
The status information includes an information processing device including at least one of information indicating whether the electronic stethoscope is powered on or off and information indicating whether the electronic stethoscope is measuring. .. The information processing apparatus according to any one of claims 1 to 6,
The information processing apparatus further comprising a second display control unit that controls the display content of the second display unit to be viewed by the patient based on the state information. The information processing apparatus according to claim 7,
The said 2nd display control part is an information processing apparatus which controls the timing which displays the guide information regarding the use of the said electronic stethoscope on the said 2nd display part based on the said state information. The information processing apparatus according to any one of claims 1 to 8,
Based on the sound data acquired by the electronic stethoscope, further comprising a detection unit for detecting an abnormality of the patient,
The information processing apparatus, wherein the first display control unit causes the first display unit to display a message indicating that the abnormality has been detected, when the detection unit detects the abnormality. A system comprising the information processing apparatus according to any one of claims 1 to 9 and the electronic stethoscope. An acquisition step of acquiring status information indicating the status of an electronic stethoscope for auscultating a patient,
A first display control step of controlling the display content of the first display section which the doctor should see based on the state information. A program that causes a computer to execute each step of the information processing method according to claim 11.

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