JP6308451B2 - Voice recorder system and voice recorder - Google Patents

Description

  The present invention relates to a voice recorder system that records conversations exchanged between a plurality of persons engaged in operations and work, and a voice recorder and a base station that constitute the system.

  Unfortunately, human attention is limited, and unfortunately, there are not a few errors (hereinafter referred to as “human errors”) in operations and tasks involving humans. Not all human errors cause serious consequences, but some human errors can cause serious consequences. Therefore, at present, investigation of the cause of human error is required under the premise that “human beings are wrong”. Under such recognition, voice recorder systems are already in practical use in some fields. For example, a part of a vehicle or an aircraft is equipped with a voice recorder system that can record voice data up to the point when an abnormality such as an impact is detected.

JP 2004-224183 A JP 2009-3311 A

  The above-mentioned voice recorder system basically assumes a situation where one or several people operate or steer related equipment or the like while sitting on a specific seat. For this reason, this type of voice recorder system is generally fixedly mounted on a vehicle or the like, and it is generally easy to identify the recorded voice. In such a technical field, the existing voice recorder system works well.

  However, a voice recorder system suitable for a situation where many people collaborate in an environment where each person can freely move, such as an operating room or a work site, does not exist or function as far as the applicant knows. Is insufficient. For example, there is a mechanism for recording a conversation during surgery through a single recording microphone arranged in the operating room, but since the operating room is large, not all voices can be clearly recorded. Further, in the conventional system, since the voices of a plurality of people are recorded at a time, it is difficult to associate the speaker with the utterance content, which hinders the subsequent verification work.

  In addition, the ex-post verification work is important not only for human error verification, but also for improving the system and environment widely. For example, when troubles such as accidents occur, the need for a mechanism capable of verifying how humans responded to the troubles after the fact is expected to increase in the future. Hereinafter, the term “troubles such as accidents” is used in the present specification to include “human error”.

  Therefore, the applicant proposes a voice recorder system suitable for a scene where many people collaborate in an environment where each person can move freely. Specifically, it is a voice recorder system comprising a plurality of portable voice recorders and a base station to which a plurality of voice recorders are detachably mounted, wherein the base station comprises (1) voice recorder When the recorder is installed, a charging unit that charges the built-in battery, (2) the master clock, and (3) when the voice recorder is installed, the voice data is read from the built-in memory and stored in the internal or external memory. A first control unit that stores in the device; and (4) a second control unit that synchronizes the built-in clock with the time of the master clock when the voice recorder is mounted. (1) a microphone; (2) the built-in battery; (3) the built-in clock; and (4) audio data input from the microphone. Recording the internal memory, and (5) starting recording of audio data triggered by the removal of the own device from the base station or receiving a simultaneous recording command, and detecting the attachment of the own device to the base station as a trigger A voice recorder system having a recording control unit for stopping recording of voice data is proposed.

  ADVANTAGE OF THE INVENTION According to this invention, the sound which each person uttered in the scene where many people cooperate in the environment where each person can move freely can be recorded separately and clearly. For this reason, even when trouble such as an accident is verified later, the speaker and the content of the utterance can be easily specified. Further, according to the present invention, the built-in clock of the voice recorder is synchronized with the master clock of the base station at the time of recording. Therefore, even when a plurality of voice recorders are used, it is possible to correctly verify the context of the utterance generation timing. Also, according to the present invention, voice recording is automatically started when the voice recorder is removed from the base station or when a simultaneous recording command is received, and when the voice recorder is attached to the base station again. Stop automatically. As described above, in the case of the present invention, since the operation of each individual does not intervene in voice recording, it is possible to eliminate forgetting to record and intentional escape from recording.

The figure which shows the structural example of the voice recorder system which concerns on an Example. The figure which shows the internal structural example of a voice recorder. The figure explaining the example of a format of audio | voice data. The figure which shows the internal structural example of a base station. The figure which shows the internal structural example of a computer. The figure which shows an example of a user interface screen. The figure explaining the processing operation of each part at the time of use.

  In the following embodiment, when it is necessary for the sake of convenience, the description will be divided into a plurality of sections or embodiments. Unless otherwise specified, they are not irrelevant to each other, and one is in the relationship of some or all of the other, modification, application, detailed explanation, supplementary explanation, and the like. Further, in the following embodiments, when referring to the number of elements (including the number, numerical value, quantity, range, etc.), especially when clearly indicated and when clearly limited to a specific number in principle, etc. Except, it is not limited to the specific number, and may be more or less than the specific number.

  Furthermore, in the following embodiments, the constituent elements (including element steps and the like) are not necessarily indispensable unless otherwise specified and apparently essential in principle. Similarly, in the following embodiments, when referring to the shapes, positional relationships, etc. of the components, etc., the shapes are substantially the same unless otherwise specified, or otherwise apparent in principle. And the like are included. The same applies to the above numbers (including the number, numerical value, quantity, range, etc.).

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Note that components having the same function are denoted by the same or related reference symbols throughout the drawings for describing the embodiments, and the repetitive description thereof is omitted. In the following embodiments, the description of the same or similar parts will not be repeated in principle unless particularly necessary.

Example 1
(Overall system configuration)
FIG. 1 shows a configuration example of a voice recorder system according to the present embodiment. A voice recorder system 1 according to the embodiment includes a plurality of voice recorders 2, a base station 3, and a computer 4 that are worn or carried by a person engaged in operation or work.

  In the case of this embodiment, the voice recorder 2 is assumed to be a small and lightweight IC recorder so that it can be easily worn or carried by the operator. In the case of the present embodiment, it is assumed that the voice recorder 2 is used, for example, in a state of being worn in a breast pocket or the like or being hung on a neck by a strap. The shape of the voice recorder 2 is not limited to a rectangular parallelepiped shape as shown in FIG. 1, but may be a card shape. For example, the function of the voice recorder 2 may be accommodated in a card-type plate such as an employee ID card or name plate.

  It is assumed that at least one microphone 21 is disposed on the surface of the casing of the voice recorder 2, and a terminal for external communication may be disposed on the surface of the casing depending on the product form. However, when a wireless technology is used for external communication, a terminal for external communication is not necessary. The detailed internal configuration of the voice recorder 2 will be described later.

  On the upper surface of the base station 3, there are provided 32 unillustrated mounting portions (for example, mounting ports) for detachably mounting the voice recorder 2. Therefore, in the base station 3 shown in FIG. 1, 32 voice recorders 2 can be mounted at a time.

  The timing of mounting and removal of the plurality of voice recorders 2 on the base station 3 is arbitrary. The voice recorder 2 may be attached to any of the 32 attachment parts where the voice recorder 2 is not attached.

  The number of mounting portions provided in the base station 3 does not give an upper limit on the number of voice recorders 2 handled in this system. That is, it is possible to handle voice data of the voice recorder 2 that is equal to or more than the number of mounting portions. This is because the voice data and the voice recorder 2 can be uniquely associated if a code for uniquely identifying the voice recorder 2 used for recording is recorded in the header area of the voice data. Therefore, the base station 3 only needs to have at least one mounting portion.

  Inside the casing of the base station 3, for example, a charging unit (for example, a power supply terminal, a non-contact power feeding coil) is disposed. The charging unit is arranged to charge a built-in battery (secondary battery) of the voice recorder 2. The charging unit is arranged corresponding to each mounting portion. Incidentally, the charging unit includes a power supply device that generates a direct current for charging from a commercial power supply, and a charge control circuit that controls the direct current for charging.

  In addition, a communication interface for realizing data communication with the mounted voice recorder 2 is prepared in each mounting unit. The communication interface is composed of, for example, one or a plurality of terminals that make contact with an electrode terminal on the voice recorder 2 side to form an electric circuit, a transmission / reception unit that realizes non-contact communication with the voice recorder 2 through electromagnetic waves or light, and the like. Is done.

  In the case of FIG. 1, the base station 3 is configured by a single housing, but a plurality of sub-base units may be mechanically and electrically connected to be used as the base station 3. In the case of the base station 3 in which a plurality of sub-base units are connected, the size of the base station 3 can be adaptively changed according to the number of voice recorders 2 to be managed.

  When the base station 3 is configured by connecting a plurality of sub-base units, a mechanism capable of specifying one master clock managed by the connected sub-base units is installed. For example, a mechanism for synchronizing the time of the master clock of one of the sub-base units with the time of the master clock of another sub-base unit may be installed, or the master of a specific sub-base unit specified by the system administrator A mechanism for synchronizing the time of the master clock of another sub-base unit with the time of the clock may be mounted.

  The computer 4 provides a function of reading the voice data of each voice recorder 2 from the base station 3 and managing it collectively. This function is provided as a function of software (program) executed by the computer 4. It is desirable that the software used in this embodiment can be collectively managed including not only audio data acquired by the voice recorder 2 but also audio data acquired from a fixed microphone (not shown) and image data taken by a video camera. . In addition, the software contains information on the settings and operations of various devices and devices that are placed and used at the site where sound and images are collected, as well as humans and objects that are work targets and monitoring targets (combinations of devices and devices). Recording data measured from the body) may also be mounted. In the case of the present embodiment, the computer 4 is directly connected to the base station 3 by a communication method compliant with the USB standard (whether wired or wireless). This is to ensure security. When security is ensured by communication encryption or the like, the computer 4 and the base station 3 may be connected via a LAN network. In this case, the computer 4 and the base station 3 may be connected using a router or a hub (HUB), or the computer 4 and the base station 3 may be directly connected using a cross LAN cable.

(Internal configuration of each device)
(Internal structure of voice recorder)
FIG. 2 shows the internal configuration of the voice recorder 2 used in this embodiment. The voice recorder 2 shown in FIG. 2 includes a microphone 21, LSI 22 (CPU 22A, encoder 22B), built-in memory 23, built-in clock 24, A / D converter 25, communication interface 26, internal bus 27, and built-in battery 28.

  The microphone 21 may be a directional microphone or an omnidirectional microphone. The presence / absence of directivity depends on the assumed mode of use. In addition, in order to avoid an operation that intentionally prevents voice recording or forgetting to record, the voice recorder 2 in this embodiment is not provided with a power button, a recording start button, a recording stop button, or the like on the surface of the casing. As will be described later, sound recording is automatically started by detaching the voice recorder 2 from the base station 3 or the like, and is automatically ended by attaching the voice recorder 2 to the base station 3.

  It should be noted that a large number of microphones 21 and sound collection openings may be provided on the surface of the housing so that an operator cannot intentionally avoid recording sound by covering the microphone 21 with a hand. . Further, a bone conduction type microphone may be used.

  The microphone 21 outputs an analog electrical signal corresponding to the sound wave characteristics to the A / D converter 25. The A / D converter 25 converts an analog electric signal corresponding to the sound wave identification into a digital electric signal at a predetermined sampling frequency, and outputs the digital electric signal to the internal bus 27.

  The LSI 22 includes a CPU 22A and an encoder 22B. The encoder 22B encodes the digital electrical signal described above into a format specific to a predetermined system. In this specification, the encoded data is referred to as audio data. In audio data, audio data (that is, main body data) may be stored in the storage area without being compressed, but may be compressed in accordance with a known compression format and stored in the storage area. Further, a silence period determination function may be provided, and a method of not recording audio data during a period determined as silence may be employed, or audio data during a period determined as silence may be significantly compressed.

  FIG. 3 shows an example format of audio data. FIG. 3 shows a data structure of a unit frame acquired at a predetermined sampling period. The unit frame includes header data 31 and audio data 32, and the header data 31 includes a header 311, time data 312, and a device identifier (ID) 313. The header data 31 also records other management information. The time data 312 records the time of the built-in clock 24 at the time when the audio data 32 is acquired. In the device identifier 313, a combination of manufacturer information, model number, serial number, and the like stored in a ROM (not shown) in the LSI 22 is recorded. When the administrator gives a unique identifier (for example, wearer name, management number) to the individual voice recorder 2 for management, the unique identifier is assigned to the voice recorder 2. It may be read from the mounted non-volatile RAM (not shown) and given to the device ID 313.

  The CPU 22A is an arithmetic device that executes firmware stored in a ROM (not shown) or the like. As will be described later, the CPU 22A controls the operation of storing the audio data in the internal memory 23, and also executes the operation of synchronizing the time of the built-in clock 24 with the time of the master clock built in the base station 3.

  The built-in memory 23 is a storage medium that stores audio data generated by the encoder 22B. The built-in memory 23 is assumed to be a semiconductor memory, for example, but a hard disk may be used as a storage medium. However, it is assumed that the built-in memory 23 has a sufficient storage capacity for the amount of audio data generated within the estimated usage time. In this embodiment, the voice recorder 2 is attached to the base station 3 at least once a day for charging.

  The built-in clock 24 is a clock used for recording the recording time of audio data. However, the built-in clock 24 is a clock that gives a specific local time to each voice recorder 2, and a synchronization relationship with other voice recorders 2 constituting the system is generally not guaranteed. Therefore, in this system, while the voice recorder 2 is attached to the base station 3 for charging or the like, the internal clock 24 of each voice recorder 2 is synchronized with the master clock in the base station 3, thereby The synchronization relationship between the built-in clocks 24 of the plurality of voice recorders 2 constituting is guaranteed. The internal clock 24 may be synchronized with a mechanism that synchronizes with the Internet time through wireless communication. However, the voice recorder 2 does not always have a wireless communication function, and the site where the voice recorder 2 is used. The communication environment is not always good. Therefore, in this embodiment, the synchronization process of the internal clock 24 is executed using the time when the voice recorder 2 is mounted on the base station 3.

  The communication interface 26 is a communication device used for transmission of audio data to the base station 3 and transmission / reception of synchronization control signals. For example, when a communication terminal is provided on the surface of the casing of the voice recorder 2, the communication interface 26 transmits and receives data (data necessary for transmission of audio data and time synchronization) to and from the base station 3 by wired communication. On the other hand, when the communication terminal is not provided on the surface of the casing of the voice recorder 2, the communication interface 26 transmits and receives data (data necessary for transmission of voice data and time synchronization) to and from the base station 3 by wireless communication (for example, bluetooth). To do. However, the communication interface 26 does not have to be either wired communication or wireless communication, and may support both wired communication and wireless communication. The internal bus 27 is a communication path for transmitting and receiving data signals between the units shown in FIG.

  The built-in battery 28 is a battery that supplies power to the internal devices constituting the voice recorder 2. A secondary battery is used as the built-in battery 27. For this reason, the built-in battery 28 needs to be charged periodically. At the time of charging, the voice recorder 2 is mounted on the mounting portion of the base station 3. As described above, it is essential to attach the voice recorder 2 to the base station 3 to charge the built-in battery 28. Using this wearing period, the time of the built-in clock 24 is set to the time of the master clock built in the base station 3. Synchronize with. As a result, at the start of recording, the time of the built-in clock 24 of all the voice recorders 2 constituting the voice recorder system can be synchronized with the time of the master clock. Incidentally, charging of the built-in battery 28 may be performed directly through the power supply terminal or may be performed in a non-contact manner.

  In addition, the casing of the voice recorder 2 may be provided with an indicator that indicates the remaining charge, an indicator that indicates that recording is in progress, and the like.

(Internal configuration of base station)
FIG. 4 shows the internal configuration of the base station 3 used in this embodiment. The base station 3 shown in FIG. 4 includes an LSI 31 (CPU 31A), a storage device 32, a master clock 33, a charging unit 34, a communication interface 35, an internal bus 36, and a power supply unit 37.

  The LSI 31 has a CPU 31A. The CPU 31A is an arithmetic device that executes firmware stored in a ROM (not shown) or the like. Through execution of the firmware, the CPU 31A, for example, confirms the mounting of the voice recorder 2 on the mounting unit, confirms the removal from the mounting unit of the voice recorder 2, reads and stores the voice data, and synchronizes the internal clock 24 of each voice recorder 2. Control processing.

  The storage device 32 is a storage area for storing audio data read from each voice recorder 2 attached to the attachment unit. The storage device 32 is composed of, for example, a semiconductor memory or a hard disk. The storage capacity of the storage device 32 is set in consideration of the number of voice recorders 2 managed by the present system and the expected amount of audio data. However, when adopting a method of sequentially transferring audio data read from the voice recorder 2 to the computer 4, a very large storage capacity is not required. The storage device 32 does not need to be built in the base station 3 and may be externally connected.

  The master clock 33 is a clock that gives a reference time (master time) of all the devices constituting the voice recorder system. At least, the master clock 33 provides the master time to the built-in clock 24 of each voice recorder 2. In the case of the present embodiment, a system composed of a plurality of voice recorders 2 is assumed. However, when time synchronization is required even with a video device (not shown) or the like, for other devices as well, A master time may be provided, or a mechanism that synchronizes the time with a master clock (not shown) that manages the master time of the entire system including other video equipment and the like may be employed. In this case, the time information of the master clock 33 is transmitted to all devices that require a synchronization relationship through wired communication or wireless communication.

  Incidentally, the master clock 33 includes, for example, a function that synchronizes with a time received via the Internet (so-called Internet time synchronization function), a function that receives a standard radio wave and automatically corrects a time error (so-called radio clock function), a telephone A function of receiving time information via a line and automatically correcting a time error may be installed. However, the master clock 33 may not have a function of automatically synchronizing with the domestic standard time. Even in that case, as long as time synchronization is ensured between all the devices constituting the voice recorder system, there will be no trouble in the subsequent verification.

  The charging unit 34 includes a power supply device and a charging control circuit, and is arranged corresponding to each mounting portion. In the case of the present embodiment, 32 charging units 34 are provided. As described above, the charging unit 34 includes a power supply device that generates a direct current for charging from a commercial power source and a charge control circuit that controls the direct current for charging.

  The communication interface 35 is a communication device used for reading voice data from the voice recorder 2 and transmitting it to the computer 4. The communication interface 35 is also used for transmission / reception of a synchronization control signal executed with the voice recorder 2. For example, when a communication terminal is provided on the surface of the casing of the voice recorder 2, the communication interface 35 communicates with the voice recorder 2 and data (data necessary for audio data transmission and time synchronization (for example, the synchronization control signal described above) by wired communication. )). On the other hand, when the communication terminal is not provided on the housing surface of the voice recorder 2, the communication interface 35 transmits and receives data (data necessary for transmission of voice data and time synchronization) to and from the voice recorder 2 by wireless communication. However, the communication interface 35 does not need to be either wired communication or wireless communication, and may support both wired communication and wireless communication. Similarly, the communication interface 35 executes communication conforming to the USB standard with the computer 4. This communication may be wired communication or wireless communication.

  The internal bus 36 is a communication path for transmitting and receiving data signals between the units shown in FIG. The power supply unit 37 is a device that generates DC power to be supplied to the internal circuit of the base station 3 from AC power.

(Internal configuration of computer)
FIG. 5 shows the internal configuration of the computer 4 used in this embodiment. The computer 4 shown in FIG. 5 includes an LSI 41 (CPU 41A, decoder 41B), a storage device 42, a monitor 43, an input device 44, a communication interface 45, an internal bus 46, and a power supply unit 47. The computer 4 does not have to be a computer dedicated to this system, and may be a general-purpose computer.

  The LSI 41 includes a CPU 41A and a decoder 41B, and reads necessary management information from the audio data received by the decoder 41B and reproduces the audio data. The CPU 41A is a computing device that executes software stored in a ROM (not shown), the storage device 42, and the like, and generates a screen for managing all audio data and the like to be managed as a list and monitors the monitor 43. The operation displayed on the screen is executed. Note that when a program other than the present system is installed, the CPU 41A also executes a processing operation according to the other program.

  The storage device 42 is a storage area for storing audio data extracted from the base station 3. Normally, a hard disk device having a storage capacity larger than that of the storage device 32 of the base station 3 is used as the storage device 42. However, a semiconductor memory or the like can be used as the storage device 42. Further, the storage device 42 does not have to be a built-in type, and may be an external connection type storage device connected via a network or a server for storing data. The storage device 42 also includes software (for example, a program for decoding audio data recorded in a specific format and a collected audio data required for collective management of audio data of a plurality of voice recorders 2 to be managed. A program for displaying data in a list on the screen is also stored.

  The monitor 43 is an output device that displays a screen that enables a list management of all audio data to be managed, and includes, for example, a liquid crystal display device, an organic EL display device, and other display devices.

  FIG. 6 shows an example of the screen 61 displayed on the monitor 43. The screen 61 includes an audio track 62 display field corresponding to audio data recorded by each voice recorder 2, a video track 63 display field corresponding to video data recorded by a video camera, and a time track 64. The The number of audio tracks 62 is displayed for the number of voice recorders 2. Of course, when the number of voice recorders 2 to be managed is larger than the display size, only a part of them may be selectively displayed. Similarly, the number of video tracks 63 matches the number of video cameras managed by this system. The screen 61 displays a sound waveform of sound data (audio data) corresponding to the time band displayed on the time track 64. The playback position is indicated by a timeline 65.

  On the screen 61, the user can selectively play back only the sound data of a specific track or play the sound of all the recorders at once through the operation of a mouse pointer (not shown). Note that the synchronization processing between tracks is realized through software executed by the CPU 41A. The video track 63 displays representative frames extracted or registered for each scene.

  The input device 44 is a device such as a mouse, a pointing device, a keyboard, or a touch pad used for operation input to the computer 4. The communication interface 45 is a communication device used for data communication with the base station 3. The internal bus 46 is a communication path for transmitting and receiving data signals between the units shown in FIG. The power supply unit 47 is a device that generates DC power to be supplied to the internal circuit of the computer 4 from AC power.

(Processing operation example)
FIG. 7 shows an operation example of use of the voice recorder system according to the present embodiment. Note that the use operation example is an example and is not limited to the procedure shown in FIG. Further, in FIG. 7, for the sake of simplicity of explanation, the voice recorder 2 is shown as if it is one, but in actuality, in each of the number of voice recorders 2 constituting the system, The operation shown in 7 is executed in parallel.

  The first processing operation is executed independently by the CPU 31A of the base station 3 and the CPU 22A of the voice recorder 2. That is, the CPU 31A of the base station 3 determines whether or not the voice recorder 2 is attached to any of the attachment portions (701). On the other hand, the CPU 22A of the voice recorder 2 determines whether or not the own apparatus is attached to any of the attachment portions of the base station 3 (702). Both CPUs determine whether or not the other is attached until a positive determination result is obtained.

  The CPU 31A that detects the mounting of the voice recorder 2 on the base station 3 instructs the voice recorder 2 that is newly confirmed to be mounted to read out voice data (703). On the other hand, the CPU 22A of the voice recorder 2 that has detected the attachment to the base station 3 ends the recording of the voice data in its own device (704). In other words, the CPU 22A stops recording audio data into the built-in memory 23.

  Thereafter, the CPU 22A receives an instruction to read out audio data, and sequentially outputs the audio data stored in the built-in memory 23 to the base station 3 (705). The output of the audio data to the base station 3 is continued until it is confirmed that all of the audio data stored in the built-in memory 23 has been normally transmitted. Incidentally, the CPU 22A may erase the audio data that has been read out, or may overwrite it during the next recording. On the other hand, the base station 3 stores the audio data received from the attached voice recorder 2 in a free area of the storage device 32 (706).

  Next, the CPU 31A of the base station 3 determines whether or not the voice recorder 2 from which the voice data has been read out needs to be charged (707). In FIG. 7, the determination as to whether charging is necessary is executed after the completion of the audio data reading, but is executed before the audio data reading instruction (703) or in parallel with the audio data reading. Also good. When it is determined that charging is necessary, the CPU 31A of the base station 3 instructs the corresponding charging unit 34 to charge the built-in battery 28 of the attached voice recorder 2. Thereby, charging of the built-in battery 28 by the charging unit 34 is started. This charging execution (708) is repeated until the end of charging is confirmed by the CPU 31A (709).

  When charging is not required or when charging is completed, the CPU 31A of the base station 3 instructs the voice recorder 2 to synchronize the time of the built-in clock 24 with the time of the master clock 33 (710). This synchronization instruction is repeatedly executed, for example, at regular time intervals until the removal of the voice recorder 2 is confirmed, for example (711). However, the time synchronization process may be executed at least once before the voice recorder 2 is removed from the base station 3. In some embodiments, the voice recorder 2 is prevented from being detached from the base station 3 through a lock mechanism (not shown) until at least reading of audio data, time synchronization processing, and execution of sufficient charging are confirmed. May be.

  In FIG. 7, the process of synchronizing the time of the built-in clock 24 with the time of the master clock 33 is executed after the charging of the built-in battery 28 is completed, but the synchronization process is executed prior to the audio data reading process. Alternatively, it may be executed in parallel with the audio data reading process and the charging operation of the internal battery 28.

  When the CPU 22A of the voice recorder 2 is instructed to execute time synchronization processing from the base station 3, the CPU 22A executes processing for synchronizing the time of the built-in clock 24 with the time of the master clock 33 notified from the base station 3. (712). This synchronization process is repeatedly executed every time an instruction is received until it is detected that the apparatus is detached from the base station 3 (713). Here, when the CPU 22A of the voice recorder 2 detects that its own device has been removed from the base station 3, it automatically starts a voice recording operation (714). In FIG. 7, the CPU 22A of the voice recorder 2 repeats the synchronization process while the removal from the base station 3 is not confirmed. However, after the execution of the synchronization process is confirmed even once, the time synchronization process is performed. It is good also as a mechanism not to execute.

  As described above, in the case of the present embodiment, the voice recording in the voice recorder 2 is automatically executed from the removal from the base station 3 to the mounting to the base station 3. That is, the voice recording by the voice recorder 2 is performed regardless of the intention of the person wearing the voice recorder 2. The voice data of each voice recorder 2 collected on the base station 3 side is further read out by the computer 4 and managed as individual audio tracks on the screen 61 described above.

(Effect of Example 1)
If the voice recorder system according to the present embodiment is employed, the voices of the individual engaged in the operation and work can be individually recorded in the voice recorder 2 worn by the individual. If a voice recorder system is simply constructed using a plurality of voice recorders 2, it is not possible to guarantee time synchronization between the built-in clocks 24 built in the individual voice recorders 2. It is difficult to accurately determine the order of sound generation due to the time of sound generation and the relationship with other speakers. However, in the case of this embodiment, since the time of the built-in clock 24 of all the voice recorders 2 can be synchronized with the time of the master clock 33 while the voice recorder 2 is attached to the base station 3, the voice of each individual person can be synchronized. The generation order of voices can be accurately determined according to the occurrence time of the voice and the relationship with other speakers. For this reason, the voice recorder system according to the present embodiment is very effective in investigating the cause of troubles such as accidents afterwards and taking measures to prevent recurrence.

  In the case of the present embodiment, since the voice recorder 2 keeps recording the voice automatically while being detached from the base station 3, it is possible to reliably avoid the situation where the voice is not recorded due to an erroneous operation or an intentional operation. can do. That is, in the case of the present embodiment, recording of all voices is guaranteed, and the cause of troubles such as accidents can be investigated.

  In the case of the present embodiment, a recording format unique to a system that stores time data in addition to audio data is adopted as a format of audio data. That is, a unique format other than the general-purpose format is adopted. As a result, the reproduction of the audio data can be limited to the computer 4 on which the dedicated software is installed, and subsequent alteration can be prevented.

  Further, in the case of the present embodiment in which sound is directly recorded on the voice recorder 2 worn by each person, there is no concern that the radiated radio wave affects the operation of the peripheral device unlike a system using a wireless microphone. For this reason, the voice recorder system according to the present embodiment can be used in various fields. In addition, unlike the system using a wireless microphone, the system in which each person wears the voice recorder 2 as in the present embodiment is likely to affect the recording situation due to obstacles existing around and the positional relationship of the wearer. No worries about recording omissions or significant deterioration in recording quality.

(Other examples)
(Example 1)
In the above-described first embodiment, the case where the voice recording is automatically started at the timing when the voice recorder 2 is detached from the base station 3 has been described. That is, the case where voice recording by the voice recorder 2 is started individually has been described. However, a simultaneous recording start button for all voice recorders 2 is provided on the base station 3 or the like, and a voice is triggered by reception of a simultaneous recording command transmitted to all the voice recorders 2 when the button is operated. You may adopt a mechanism to start recording all at once.

(Example 2)
In the first embodiment described above, only the case where the software that provides the screen 61 capable of managing the audio data corresponding to each voice recorder 2 is installed in the computer 4 has been described. However, the computer 4 may also be installed with software that automatically converts individual voice data into text data using voice recognition technology.

(Example 3)
In the first embodiment described above, on the assumption that the synchronization of the time data 312 stored in the header of the individual audio data is guaranteed, the individual audio data is stored on the time track 64 based on the time data 312. The case where it arranges in was demonstrated. However, the time lag gradually accumulates in the built-in clock 24 after the voice recorder 2 is removed from the base station 3. Therefore, the software that provides the screen 61 may be equipped with a function for finely correcting the time axis of the plurality of audio data based on the sound that appears in common in the plurality of audio data. In addition, the software that provides the screen 61 may be equipped with a function of clarifying the voice of the individual wearing the voice recorder 2 by removing the voice that appears in common in the plurality of voice data from each voice data. .

(Example 4)
In the first embodiment described above, the device configuration in which the speaker is not incorporated as the voice recorder 2 has been described. However, the voice recorder 2 with a speaker may be used. When the speaker is mounted, for example, a noticeable decrease in the remaining capacity of the storage area or the remaining battery level due to the voice recorder 2 not being returned to the base station 3 for a long time may be notified by the generation of an alarm sound. . In this case, each determination threshold value may be determined according to each capacity.

  In addition, when the base station 3 is not provided with a lock mechanism, if the voice recorder 2 is removed when charging of the built-in battery 28 or voice data is not sufficiently read from the base station 3, May be notified by the generation of an alarm sound, and the user may be prompted to attach to the base station 3, or the alarm sound may be continuously generated so that it cannot be used as it is.

(Example 5)
In the above-described first embodiment, a general apparatus configuration and processing operation are described without assuming application to a specific technical field, but the system is applied to, for example, a voice recorder system in the medical field. Is preferred. In the medical field, if this system is used in the field of surgery and emergency medicine, it will be effective for the development of medical technology in the future.

  For example, an electrocardiogram monitor or an alarm device (alarm) used at a site such as surgery or emergency medical care is generally loud. For this reason, in the recording by the existing voice recorder system (for example, a system in which one voice recorder is fixedly arranged in the room), there is a technical problem that only sound such as an electrocardiogram is conspicuously recorded and it is difficult to hear the sound. In general, since an operating room or the like has a structure in which sound is likely to reverberate, there is a technical problem that in recording by an existing voice recorder system, it is difficult to hear sound due to superposition of echoes (reverberation sound).

  However, if the voice recorder system described in the first embodiment is used, the voice recorder 2 is attached to each of the staff engaged in medical treatment, so that the voice of each individual can be clearly recorded by using a particularly highly directional microphone. The verification work at a later date can be carried out efficiently.

  When the system described in the first embodiment is applied to the medical field, patient biological information collected through a measuring instrument such as an electrocardiogram monitor or a sphygmomanometer with respect to the time axis of audio data or imaging data. These time axes may be synchronized so that they can be observed on the screen.

  In addition, if the voice recorder 2 can be connected and linked with communication equipment (wireless devices, telephones (fixed telephones, extension telephones), mobile phones, PHS, smartphones, intercoms, etc.), accident sites, construction sites, work sites In the operation room or the like, the number of people who are engaged in the work and the movement of each person is not restricted, and it can be expected to be highly effective for voice recording when the work proceeds through voice confirmation and instructions. For example, when the sound from various sound sources around the site (for example, wind noise, sound generated by equipment or alarms used for work, noise of hustle, etc.) is loud, the operator's voice is drowned out by those surrounding sounds. Can be difficult to hear. However, in the case of the voice recorder system described in the first embodiment, since the voice recorder 2 can be attached to each person, the voice of each individual can be clearly recorded by using a microphone having high directivity. Ex-post verification work can be done efficiently.

DESCRIPTION OF SYMBOLS 1 ... Voice recorder system 2 ... Voice recorder 3 ... Base station 4 ... Computer 21 ... Microphone 23 ... Built-in memory 24 ... Built-in clock 28 ... Built-in battery 33 ... Master clock 34 ... Charging unit 61 ... Screen 62 ... Audio track 63 ... Video track 64 ... Clock track 65 ... Timeline

Claims (6)

A voice recorder system comprising a plurality of portable voice recorders and a base station to which a plurality of voice recorders are detachably mounted,
The base station is
(1) When a voice recorder is installed, a charging unit that charges its built-in battery,
(2) Master clock and
(3) when the voice recorder is mounted, a first control unit that reads voice data from its built-in memory and stores it in a built-in or external storage device;
(4) a second control unit that synchronizes the built-in clock with the time of the master clock when the voice recorder is mounted;
The voice recorder
(1) a microphone;
(2) the built-in battery;
(3) the built-in clock;
(4) the built-in memory for recording audio data input from the microphone;
(5) Start recording audio data triggered by removal of own device from base station or reception of simultaneous recording command, and stop recording audio data triggered by detection of own device attached to base station A voice recorder system comprising a recording control unit. The voice recorder system according to claim 1,
The voice data is provided with clock data of the built-in clock built in each of the voice recorders,
A computer that reads out a plurality of audio data corresponding to the plurality of voice recorders from the base station assigns the plurality of audio data to different audio tracks, and displays the list as a list. The voice recorder system according to claim 2,
The voice recorder system, wherein the computer displays measurement information collected through a measuring instrument on an audio track corresponding to the plurality of audio data and another track synchronized in time. A voice recorder that is portable and detachably attached to the base station,
A microphone,
A built-in battery that is charged when attached to the base station;
A built-in clock that is automatically synchronized to the time of the master clock of the base station when attached to the base station;
A built-in memory for recording audio data input from the microphone;
A recording control unit for starting recording of voice data triggered by the removal of the own device from the base station or receiving a simultaneous recording command, and stopping the recording of the voice data triggered by detection of attachment of the own device to the base station; A voice recorder characterized by comprising: The voice recorder according to claim 4,
When the remaining battery capacity of the built-in battery falls below a first threshold and / or when the remaining capacity that can be stored in the built-in memory falls below a second threshold, a first alarm sound is generated. A voice recorder comprising a control unit. The voice recorder according to claim 4,
When the battery level of the built-in battery is less than or equal to a second threshold when the device is removed from the base station, and / or there is audio data that has not been transmitted from the built-in memory to the base station And a second control unit for generating an alarm sound.

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