JP2015166869A - Recording device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a recording device in which a voice file generated by performing a recording operation by the recording device is transferred to an external processing device connected to the recording device.SOLUTION: Voice data is generated by processing a voice signal outputted from a microphone 202, and a first voice file storing this voice data is stored in a recording medium 208. A system control part 210 successively transmits the voice data generated during a recording operation to an external processing device via a communication part 218, and receives first identification information being a file name from the external processing device. The first voice file is added with the first identification information and second identification information showing that a transmission failure detection part detects the failure of the successive transmission. A voice file reading processing part reads the first voice file added with the first and second identification information from the recording medium 208.

Description

  The present invention relates to a recording apparatus and a recording system for storing an audio file that accommodates audio data generated by the recording apparatus.

  There is a system that collects and accumulates voice data that is recorded and generated when a doctor visits a hospital.

  The voice data collected in a large hospital is used to create an electronic medical record. One session is recorded in correspondence with the medical treatment of one patient, and an audio file containing the audio data for the one session is transferred to a server or the like and recorded. The recorded audio file is reproduced by an operator in charge of documentation to create an electronic medical record or the like.

  If the system described above fails in transferring audio data and audio files, there is a possibility that important records may be lost. In addition, doctors' medical treatment is a highly specialized action that is continuously performed, and operations and operations that are not directly related to medical care are disliked. Therefore, even if the voice data remains in a recording device such as an IC recorder carried by the doctor, it is not necessary to ask the doctor to retransfer the voice data or the voice file that has failed to be transferred. Would be impractical. Therefore, it is desired to construct a system that can automatically recover when transfer of audio data or an audio file fails.

  Japanese Patent Application Laid-Open No. 2004-228561 discloses a technique that performs backup by adding a unique sequence number to a file name of a backup target file, performs history management, and performs restoration processing based on backup and history management.

  Japanese Patent Application Laid-Open No. 2004-228561 discloses a technology that enables file backup by automatically extracting files to be backed up automatically in accordance with the purpose of file backup.

  Japanese Patent Application Laid-Open No. 2004-228688 discloses a technique that enables synchronization to be resumed in an incomplete synchronization session when a synchronization failure occurs during the synchronization of data between a client device and a server device. The

Japanese Patent Laid-Open No. 9-274581 JP 2007-164265 A JP 2009-140515 A

  When creating response records and electronic medical records by aggregating audio data (audio data files) generated by multiple physicians, who is handling the aggregated audio data files? It must be clearly distinguishable whether it was generated under In other words, it is desirable to give a file name based on a naming rule suitable for the side handling the audio file later in order to prevent work mistakes. For example, it is important to give a file name capable of discriminating a medical subject, a doctor name, a medical date and time, etc., in order to perform an efficient and error-free operation.

  On the other hand, the recording device owned by the doctor may not be able to assign a file name based on such a naming rule to the audio data file. Further, even if an arbitrary file name can be given on the recording device side possessed by the operator or doctor, it is disliked to leave the processing to the doctor.

  In this regard, in the technique disclosed in Patent Document 1, it is necessary to unify the file name naming rules throughout the entire system, and therefore it may not always be possible to assign the desired file name on the side that processes the audio data. .

  In the technique disclosed in Patent Document 2, it is necessary to separately generate and manage a file for managing the history.

  In the technique disclosed in Patent Document 3, it is necessary to store the update identifier in both the client device and the server device and exchange them with each other.

  The present invention has been made in view of the above problems, and communicates during transfer of audio data and audio files performed between the recording device and an information processing device such as a server that aggregates audio files generated by the recording device. It is an object to make it possible to restore an audio file more reliably even when a failure occurs.

(1) A typical example of the present invention is as follows. That is, the recording device
A microphone for voice input,
An audio storage processing unit that processes an audio signal output from the microphone to generate digital audio data, generates a first audio file storing the audio data, and stores the first audio file in a recording medium;
A communication unit capable of communicating with an external processing device;
A voice data transmission processing unit that sequentially transmits the voice data generated by the voice storage processing unit simultaneously with a recording operation to the external processing device via the communication unit;
In executing the recording operation, first communication information transmitted from the external processing device, which is a file name assigned to a second audio file storing the audio data in the external processing device, is transmitted to the communication unit. An identification information reception processing unit for receiving via
When there is a failure in the sequential transmission of the audio data with the external processing device, a transmission failure detection unit that detects the failure in the sequential transmission,
An audio file read processing unit that reads out the first audio file including the audio data that failed in the sequential transmission from the recording medium when the transmission failure detection unit detects the failure in the sequential transmission;
An audio file transmission processing unit that transmits the first audio file read by the audio file reading processing unit to the external processing device via the communication unit;
When the voice storage processing unit generates the first voice file, the first identification information and the communication failure detection unit have detected a failure in the sequential transmission for the voice data. And generating the second identification information that is transmission failure information indicating, and storing the first audio file after adding the first and second identification information in the recording medium,
The audio file reading processing unit reads the first audio file to which the first and second identification information are added from the recording medium.

  According to the present invention, when an audio file containing audio data generated by a recording device is stored by an external processing device, a failure in information communication occurs between the recording device and the external processing device. It is possible to prevent the loss of voice data.

It is a figure which shows the structure of a recording system roughly. It is a block diagram which shows roughly the internal structure of a recording device. It is a block diagram which shows roughly the internal structure of PC. It is a block diagram which shows roughly the internal structure of a server. It is a flowchart explaining the process sequence of the main flow performed within a recording device. It is a flowchart explaining the process sequence of the main flow performed within a recording device. It is a flowchart explaining the process sequence of the main flow performed within a recording device. It is a figure explaining the example of a format of an audio | voice file. It is a flowchart explaining the procedure of the recording process performed with each of the recording device, PC, and server which comprise a recording system. It is a flowchart explaining the process sequence following the flowchart of FIG. 7A. It is a flowchart explaining the process sequence following the flowchart of FIG. 7B. It is a flowchart explaining the process procedure following the flowchart of FIG. 7C. It is a flowchart explaining in detail the content of the untransmitted data recovery process shown in the flowchart of FIG. 7A. It is a flowchart explaining the process sequence following the flowchart of FIG. 7E. FIG. 8 is a flowchart for explaining in more detail the contents of a free memory confirmation / reservation process shown as a process by the recording apparatus in the flowchart of FIG. 7B. FIG. 8 is a diagram for explaining how the process shown in the flowchart of FIG. 7 is executed by a recording device, a PC, and a server, and information, audio data, and audio files are exchanged between the three parties. It is a figure explaining a mode that information, audio | voice data, and an audio file are exchanged between a recording device, PC, and a server, when a recording device is provided with the communication part which can communicate with PC, and the communication part which can communicate with a server.

  FIG. 1 is a block diagram illustrating a typical configuration example of the recording system 100. The recording system 100 includes a recording device 200, a personal computer (PC) 300, and a server 400. Although FIG. 1 shows a state where the recording device 200 and the PC 300 are connected to each other in a wired form, wireless connection is more suitable in the medical field. As will be described in detail later, the recording apparatus 200 and the server 400 may be configured to be directly connectable via a wired or wireless communication network.

  The PC 300 and the server 400 are connected via a network NW such as a LAN or WAN. When the recording system 100 is used, for example, in a large hospital or the like, each doctor carries a recording device 200, and a PC 300 is installed in a doctor's office or operating room, and one or a plurality of them are connected via the network NW. The server 400 is connected. Then, recording is performed during the medical practice to generate an audio file, and the audio file is collected in the server 400. Recording is basically performed for one session corresponding to one medical practice, and one audio file can be generated corresponding to the recording.

  FIG. 2 is a block diagram schematically illustrating the internal configuration of the recording apparatus 200. The recording apparatus 200 includes a microphone 202, an analog front end (AFE) 204, a digital signal processor (DSP) 206, a recording medium 208, a system control unit 210, an operation unit 212, and a display processing unit 214. And a display unit 216 and a communication unit 218.

  The microphone 202 converts the sound into an electric signal (analog sound signal) and outputs it to the analog front end 204. The analog front end 204 performs processing such as amplification, equalization, noise reduction and the like on the analog audio signal input from the microphone 202, converts the analog audio signal into a digital audio signal, and outputs the digital audio signal to the digital signal processor 206. The digital signal processor 206 performs quantization noise removal processing on the digital audio data input from the analog front end 204 and performs processing such as encoding and compression as necessary to the system control unit 210. Output.

  The system control unit 210 sequentially transmits the digital audio data input from the digital signal processor 206 to the PC 300 via the communication unit 218. The system control unit 210 also generates an audio file and records it on the recording medium 208 when the recording of one session is completed. At this time, the audio file recorded on the recording medium 208 is handled as a temporary file, as will be apparent from the following description. Of course, this audio file can be recorded in the recording medium 208 for a long time if necessary. When recording an audio file in the recording medium 208, it is possible to give a file name with a unique naming rule in the recording apparatus 200.

  The recording medium 208 is configured by a flash memory or the like, and may be a built-in type, or may be configured to be detachable from the recording device 200 in the form of a so-called memory card.

  The operation unit 212 includes a recording button, a playback button, a stop button, a fast-forward button, a fast-rewind button, a volume control button, an erase button, and the like, and accepts an operation by the user. When the system control unit 210 detects an operation of the operation unit 212 by the user, information regarding the detected operation content, that is, operation information is transmitted to the PC 300 via the communication unit 218. As will be described in detail later, a command corresponding to the operation information is transmitted from the PC 300 to the recording apparatus 200. The system control unit 210 receives this command via the communication unit 218 and starts an operation corresponding to the received command.

  The display unit 216 includes a liquid crystal display device, an organic EL display device, or the like, and is configured to be able to display characters, graphic information, and the like. Based on the control signal output from the system control unit 210, the display processing unit 214 controls the display unit 216 so that various displays such as an operation status, a remaining battery level, a remaining memory level, and a warning are performed. In addition, without having a display such as characters and graphs, the operating status, the remaining battery level, the remaining memory capacity, a warning, and the like may be notified by blinking a lamp.

  The communication unit 218 can have various configurations depending on the configuration of the recording system 100. For example, it may be connected to the PC 300 by USB in a wired or wireless form. Alternatively, it may be connected to the PC 300 using Bluetooth (registered trademark) or other short-range wireless communication technology. In addition to or in place of these, the PC 300 and the server 400 may be directly connectable via a wired or wireless LAN. Alternatively, in addition to the communication unit 218 being configured to be connectable to the PC 300, the communication unit 218 may be configured to be directly connectable to the server 400 via a public wireless line, a public wireless telephone line, or the like.

  FIG. 3 is a block diagram schematically showing the configuration of the PC 300. The PC 300 includes a communication unit 302, an auxiliary storage device 304, a CPU 306, a RAM 308, a network interface (interface is expressed as “I / F” in FIG. 3) 310, a display processing unit 312, a display A unit 314 and an operation input unit 316.

  The communication unit 302 is configured to be connectable to the recording device 200 and the server 400. When the communication unit 218 of the recording apparatus 200 uses a short-range wireless communication technology such as wired or wireless USB or Bluetooth, the communication unit 302 also communicates with the communication unit 218 using a corresponding technology. Configured to be possible. The communication unit 302 is also configured to be connected to the network NW via the network interface 310 and connectable to the server 400 via the network NW. When the recording device 200 is connected to the network NW via a wired or wireless LAN, the communication unit 302 is configured to be connectable to the communication unit 218 of the recording device 200 via the network NW.

  The network interface 310 is configured to be connectable to the network NW in a wired or wireless manner.

  The auxiliary storage device 304 is configured by a hard disk drive, a solid state drive, or the like, and has a relatively large storage area. The auxiliary storage device 304 is used to store a program executed on the PC 300, or to store audio data sequentially transmitted from the recording device 200 or an audio file generated by the PC 300.

  The CPU 306 interprets and executes the program read from the auxiliary storage device 304 and loaded into the RAM 308, and performs processing described later. The RAM 308 is configured by a memory having a relatively high access speed, such as a DDR SD-RAM.

  The display unit 314 is a CRT, a flat panel display, or the like, and is configured to display characters, graphics, and the like. Based on the control signal output from the CPU 306, the display processing unit 312 displays the operation state of the recording device 200, a list of audio files recorded in the auxiliary storage device 304, and the like on the display unit 314.

  The operation input unit 316 includes a keyboard, a mouse, and the like, and is configured to accept a user operation.

FIG. 4 is a block diagram schematically showing the configuration of the server 400. The server 400 includes a server main body 402, a network interface (in FIG. 4, the interface is expressed as “I / F”) 420, and an auxiliary storage device 430. The server main body 402 includes a CPU 404, a RAM 406, an output unit 408, and an input unit 410. A network interface 420 is configured to be connectable to a network NW. When the recording device 200 is configured to be connectable to a public wireless line or a public wireless telephone line as described above, the server 400 is also configured to be connectable to a base station of the public wireless line or public wireless telephone line via the network NW. Is done.

  The auxiliary storage device 430 is configured by an array of hard disk drives or the like, and has a relatively large storage area. The auxiliary storage device 430 stores a program executed on the server 400. The auxiliary storage device 430 also has a storage area for collecting and storing audio files transmitted from a plurality of PCs 300 connected to the server 400. In the case where the recording apparatus 200 and the server 400 are configured to be directly connectable, an audio file may be directly transmitted from the recording apparatus 200 to the server 400. Even in that case, the audio file is stored in the auxiliary storage device 430.

  The audio file stored in the auxiliary storage device 430 is transmitted to the client machines in response to a request from another client machine connected to the server 400 via the network NW. As an example, the client machine is a computer operated by an operator who creates an electronic medical record, a corresponding record, and the like while reproducing and listening to an audio file.

  The CPU 404 interprets and executes a program read from the auxiliary storage device 430 and loaded into the RAM 406, and performs an operation described later. The RAM 406 is configured by a memory having a relatively high access speed, such as a DDR SD-RAM.

  The output unit 408 is for displaying the connection status and communication status with other devices of the server 400, and is configured to include a flat panel display or the like. The input unit 410 includes a keyboard, a mouse, and the like, and is configured to be able to accept an operation of a server administrator.

  FIG. 5 is a flowchart schematically illustrating a processing procedure of the main flow executed by the system control unit 210 of the recording device 200. The processing shown in FIG. 5 is performed by the system control unit 210 reading, interpreting, and executing a program stored in the recording medium 208. This processing is started when the recording apparatus 200 is connected to the PC 300 and the recording apparatus 200 is turned on. At this time, it is assumed that an application program for communicating with both the recording device 200 and the server 400 and transmitting / receiving information is executed on the PC 300. Alternatively, when the recording apparatus 200 is connected to the PC 300, the application program may be automatically loaded in the PC 300 and started to be executed.

  Note that the processing executed by the PC 300 and the server 400 in conjunction with the processing executed by the system control unit 210 of the recording apparatus 200 is also shown in FIG. In FIG. 5, a step code for explaining a processing procedure executed by the system control unit 210 of the recording device 200 is given a reference sign SR at the beginning. “R” in the symbol “SR” is derived from “R” which is an initial of Recorder, that is, Recorder. A step code for explaining a processing procedure executed by the PC 300 is given a code SP at the beginning thereof. “P” in the symbol “SP” is derived from “P” of PC. Then, a step code for explaining the processing procedure executed by the server 400 is given a code SS at the head part thereof. The second character “S” in the code “SS” is derived from “S” which is an initial of the server, that is, the server.

  Here, an outline of the processing shown in FIG. 5 will be described. The recording apparatus 200 operates in a state in which it is connected to another processing apparatus such as the PC 300 (this is referred to as an “online operation mode”), and a mode in which it is not connected to another processing apparatus ( This is referred to as “stand-alone operation mode”). The process shown in FIG. 5 is assumed to be operating in the online operation mode. In this case, the system control unit 210 controls the operation of the recording device 200 in the following procedure.

  That is, when the user operates the operation unit 212, the system control unit 210 transmits operation information including the content of the user operation received by the operation unit 212 to the PC 300 via the communication unit 218. In response to the operation information, an operation command is output from the PC 300 to the recording device 200. The system control unit 210 receives this operation command via the communication unit 218. Then, an operation based on the received operation command is started. That is, in the online operation mode, the recording device 200 performs the operation shown in the flowchart of FIG. 5 in cooperation with the PC 300 as the external processing device.

When the recording device 200 is turned on, the system control unit 210 performs initial settings in the SR 500. In the initial setting, as shown in FIG. 5C, in addition to initialization (SR580) of each part of the recording apparatus 200, that is, RAM clear, port initialization, etc., the communication part 218 is initialized. Then, with SR 582 and SP 580, handshaking processing and the like with the PC 300 are performed. Thereafter, in SP582, an access permission request including information specifying the recording device 200 and information specifying the PC 300 is transmitted from the PC 300 to the server 400. The server device 400 receives the access permission request at SS580, and determines whether or not to grant the access permission to the PC 300 based on the information specifying the recording device 200 and the information specifying the PC 300 included in the access permission request ( SS582). If it is determined in the server device 400 that access is permitted, a notification of access permission is transmitted from the server 400 to the PC 300 (SS584).
The PC 300 that has received the notification of access permission in SP484 transmits a command instructing recovery to the recording apparatus 200 in SP585.

  The recording apparatus 200 that has received a recovery instruction command from the PC 300 in SR583 executes untransmitted data recovery processing in SR584. At this time, the PC 300 performs a process corresponding to the untransmitted data recovery process of the recording apparatus 200 in SP586 and the server 400 in SS586. This process will be described in detail later with reference to FIG. 7E and FIG. 7F. When the transfer of audio data has failed due to communication trouble or the like in the past, an audio file containing audio data that has not been transferred is recorded. In this process, the data is transferred from the device 200 to the server 400 via the PC 300 and stored in the auxiliary storage device 430.

  The recording apparatus initialization process (SR500) is completed by the above process, and the process waits until a user operation is detected.

  In SR502, when it is detected that the record button, the play button, the stop button, the fast forward button, the fast reverse button, etc. of the operation unit 212 of the recording apparatus 200 are operated, the operation information of the operation is transmitted to the PC 300 in SR504. The The PC 300 receives this operation information at the SP 500. The PC 300 analyzes the operation information received at SP 500 at SP 502, generates an operation command that instructs the recording device 200 to perform an operation corresponding to the operation information, and transmits the operation command to the recording device 200 at SP 504.

  The received operation command received by SR506 is determined by SR508 to SR516, and processing corresponding to the operation command is executed.

  In SR508, the system control unit 210 determines whether or not the command transmitted from the PC 300 is a recording command. If the determination in SR508 is affirmed, the process proceeds to SR550, and after a series of processes related to recording start is performed, the process proceeds to SR502. If the determination in SR508 is negative, the process proceeds to SR510.

  In SR510, the system control unit 210 determines whether the command transmitted from the PC 300 is a playback command. If the determination in SR510 is affirmed, the process proceeds to SR552, and after a series of processes related to the start of the reproduction process is performed, the process proceeds to SR502. If the determination in SR510 is negative, the process proceeds to SR512.

  In SR512, the system control unit 210 determines whether the command transmitted from the PC 300 is a fast-forward command. If the determination in SR512 is affirmed, the process proceeds to SR554, and after a series of processes related to fast-forwarding is performed, the process proceeds to SR502. If the determination in SR512 is negative, the process proceeds to SR514.

  In SR514, the system control unit 210 determines whether the command transmitted from the PC 300 is a fast reverse command. If the determination in SR 514 is affirmed, the process proceeds to SR 556, and after a series of processes related to fast rewinding is performed, the process proceeds to SR 502. If the determination in SR514 is negative, the process proceeds to SR516.

  In SR516, the system control unit 210 determines whether the command transmitted from the PC 300 is a stop command. If the determination in SR516 is affirmed, the process proceeds to SR518. On the other hand, if the determination in SR516 is negative, the process returns to SR502.

  In SR 518, it is determined whether or not a recording operation is currently performed. If the determination of SR518 is affirmed, the process proceeds to SR558. If the determination of SR518 is negative, the process proceeds to SR520.

  In SR 558 which is a branch destination when the determination in SR 518 is affirmed, a recording stop process is performed. That is, a series of operations related to recording stop is performed. When the process of SR558 is completed, the process returns to the process of SR502.

  In SR520, which is a branch destination when the determination in SR518 is denied, the system control unit 210 determines whether or not the reproduction operation is currently performed. If the determination in SR520 is affirmed, the process proceeds to SR560. On the other hand, if the determination in SR520 is negative, the process proceeds to SR522.

In SR 560 which is a branch destination when the determination in SR 520 is affirmed, a reproduction stop process is performed. That means
A series of operations related to playback stop is performed. When the process of SR560 is completed, the process returns to the process of SR502.

  In SR522, which is a branch destination when the determination in SR520 is denied, the system control unit 210 determines whether or not a fast-forward operation is currently performed. If the determination of SR522 is affirmed, the process proceeds to SR562. On the other hand, if the determination in SR522 is negative, the process proceeds to SR524.

  In SR 562, which is a branch destination when the determination in SR 522 is affirmed, a fast-forward stop process is performed. That is, a series of operations related to the fast-forward stop is performed. When the processing of SR562 is completed, the processing returns to SR502.

  In SR 524, which is a branch destination when the determination in SR 522 is denied, the system control unit 210 determines whether or not a fast reverse operation is currently performed. If the determination of SR524 is affirmed, the process proceeds to SR564. On the other hand, if the determination in SR524 is negative, the process proceeds to SR502.

  In SR 564 which is a branch destination when the determination in SR 524 is affirmed, a process of stopping fast return is performed. That is, a series of operations related to the fast reverse stop is performed. When the process of SR564 is completed, the process returns to the process of SR502.

  Next, a process (recording process) performed by each of the recording apparatus 200, the PC 300, and the server 400 when the user performs an operation for starting recording will be described. First, the outline will be described. After the start of the recording process, the recording apparatus 200 records the audio data generated during the recording operation inside the recording apparatus 200 and sequentially outputs the audio data to the PC 300 in units of blocks. The PC 300 sequentially records received audio data blocks. When the recording stop operation is performed by the user, the recorder 200 ends recording of the audio data and generates an audio file, stops transmission of the audio data, and transmits information on the stop operation to the PC 300. In the PC 300 that has received the stop operation information, an audio file including audio data is generated. In this specification, an audio file generated by the recording device 200 is referred to as a temporary audio file, and an audio file generated by the PC 300 is referred to as a recording audio file.

  The recording audio file generated by the PC 300 is transmitted to the server 400 and stored in the auxiliary storage device 430. The same file name may be assigned to the temporary audio file and the recording audio file, but in the following, different file names are assigned. The file name given to the recording audio file is issued from the server 400 at the start of the recording process. That is, the server 400 has the authority to determine the file name given to the recording audio file generated by the PC 300.

  FIG. 6 is a diagram for conceptually explaining an example of the file structure of a temporary audio file stored in the recording device 200 and a recording audio file stored in the PC 300. In the present embodiment, the description will be made assuming that both audio files are recorded in the RIFF waveform Audio Format (RIFF Wave format).

  As shown in FIG. 6, the audio file includes a RIFF header chunk, a format chunk, a file information chunk, and a data chunk. The RIFF header chunk includes “RIFF” indicating that the audio file is a RIFF format file, “size” indicating the data size of the format chunk, file information chunk, and data chunk, and indicates that the audio data file is a WAVE file. The “WAVE” data shown is stored.

  Data indicating the format of the stored audio data is stored in the format chunk, and “size” indicating the data size in the chunks “fmt” and “fmt” after the chunk header indicating that the chunk is a format chunk. ”,“ Format type ”,“ number of channels ”,“ sampling frequency ”,“ byte rate ”,“ sample size ”, and“ quantization bit number ”are stored.

  The file information chunk stores chunk header “FINF”, “size” indicating the data size in the chunk, “file information”, “transmission failure information”, and “transmission completion information”. In FIG. 6, file information is denoted by a code FI (File Information), transmission failure information is denoted by a code TF (Transfer Failure), and transmission completion information is denoted by a code TC (Transfer Complete).

  As described above, different file names are assigned to the temporary audio file stored in the recording apparatus 200 and the recording audio file stored in the PC 300. A file name issued from the server 400 is given to the recording audio file stored in the PC 300. The file information FI stores information that can specify the file name issued from the server 400. For example, if a recording audio file issued with a file name issued from the server 400 in the PC 300 and saved is incomplete or lost for some reason, the PC 300 causes the recording device 200 to On the other hand, it is possible to request the transfer of the corresponding temporary audio file. At this time, the PC 300 transmits information related to the file name issued and given from the server 400 to the recording device 200.

  The recording device 200 searches and reads a temporary audio file storing file information FI that matches the target file name from the files stored in the recording medium 208 and transfers it to the PC 300. Therefore, the temporary audio file stored in the recording device 200 and the recording audio file stored in the PC 300 can be handled even if the same file name is not given.

  For example, since it is assumed that a large number of recording audio files are transmitted from a plurality of users on the server 400 side, it is relatively long to categorize and handle these recording audio files. It may be necessary to assign a complicated file name. On the other hand, on the recording device 200 side, the size of the display unit 216 is reduced with the miniaturization of the device, and if a long file name or a complicated file name is given, the file name cannot be displayed or scrolled. It may be necessary. In this regard, it becomes possible to associate the audio file saved on the recording device 200 side with the audio file saved on the PC 300 side by the information recorded in the file information FI as described above, and each side It is possible to give a unique file name.

  When audio data is sequentially output from the recording device 200 to the PC 300, if the recording device 200 and the PC 300 are connected by a cable, audio data transmission failure may occur due to poor connector contact, noise, or the like. Further, when the recording device 200 and the PC 300 are wirelessly connected, audio data transmission failure may occur due to electromagnetic multipath, noise, interference, or the like. When this transmission failure is detected, the recording device 200 performs processing for recording information that can identify the data position where the transmission failure occurred in the transmission failure information TF. For example, when the audio data is transferred in units of data blocks each having a predetermined number of bytes, it is possible to record information that can identify the data block in which the transmission failure has occurred in the transmission failure information TF. . Or, if the audio data that caused the transmission failure is 2-channel stereo audio data, it is the right channel, left channel, or how many seconds (or what number of bytes) after recording starts. It is also possible to record information capable of specifying this in the transmission failure information TF.

  The recording audio file generated by the PC is transmitted to the server 400. After saving the received recording audio file, the server 400 transmits a notification notifying the completion of saving the audio file to the PC 300. The PC 300 transfers this notification to the recording device 200. In the recording apparatus 200, processing for recording the information on the completion of file transmission is performed in the transmission completion information TC of the corresponding temporary audio file.

  In the data chunk, a chunk header “data” indicating that the chunk is a chunk storing audio data, “size” indicating the data size of the chunk, and “audio data” data are stored.

  With reference to FIG. 7, details of processing (recording processing) performed in each of the recording device 200, the PC 300, and the server 400 when the user performs a recording start operation will be described. FIGS. 7A to 7G are flowcharts showing in more detail the procedure when the SR550 recording process in FIG. 5B is performed. In the present embodiment, as described above, recording device 200 is connected to PC 300 as an external processing device in a wired or wireless manner, and PC 300 is wired or wireless to server 400 as a second external processing device. It shall be connected in the form of. FIG. 7 shows a processing procedure executed by each of the recording apparatus 200, the PC 300, and the server 400. A step code for explaining a processing procedure executed by the recording apparatus 200 is given a code SR at the head thereof. “R” in the symbol “SR” is derived from “R” which is an initial of Recorder, that is, Recorder. A step code for explaining a processing procedure executed by the PC 300 is given a code SP at the beginning thereof. “P” in the symbol “SP” is derived from “P” of PC. Then, a step code for explaining the processing procedure executed by the server 400 is given a code SS at the head part thereof. The second character “S” in the code “SS” is derived from “S” which is an initial of the server, that is, the server.

  The main body that executes the processing shown in FIG. 7 is as follows. That is, in the recording apparatus 200, the system control unit 210 reads the program recorded on the recording medium 208 and performs SR700 and subsequent processing. In the PC 300, the CPU 306 reads an application program stored in the auxiliary storage device 304 and performs SP 700 and subsequent processing. In the server 400, the CPU 404 reads the program stored in the auxiliary storage device 430, and performs SS700 and subsequent processing. However, in the following description, for the purpose of facilitating understanding, it is assumed that the subject of each process is the recording device 200, the PC 300, and the server 400.

  As the execution of the process of SR550 in FIG. 5B is started, the recording apparatus 200 and the PC 300 start the recording process. The recording apparatus 200 performs initial setting processing in SR700. As an example, a process for reading a format for recording, monaural / stereo settings, sound quality, microphone input level, and the like, and generating a file name when generating a file in the recording apparatus 200 are performed. In the above setting, it is assumed that information related to contents preset by the user of the recording apparatus 200 is stored in the recording medium 208 or the like. The file name can be a combination of a predetermined character string and a sequential number that increments each time a file is generated.

  On the other hand, in SP700, the PC 300 performs a recording start notification transmission process and transmits a recording start notification to the server 400. The server 400 receives the recording start notification at SS700. The server 400 prepares for receiving an audio file in SS702. In this voice file reception preparation, a storage area for storing a recording voice file in the auxiliary storage device 430, a process for determining a file name, and the like are performed.

  In SS 704, the server 400 transmits file name information to the PC 300. The PC 300 receives the file name information transmitted from the server at SP702. Subsequently, in SP704, the PC 300 transmits a recording start command to the recording device 200 together with the file name information.

  The recording apparatus 200 receives the recording start command and file name information transmitted from the PC 300 via the SR 701. The recording apparatus 200 starts a recording operation in SR702. At this time, the file name information is recorded in the header information in the audio file generated when recording is completed, that is, in the additional information described with reference to FIG. Specifically, the file name information is recorded in the file information FI in the file information chunk. Incidentally, in SP704, the PC 300 may transmit information such as a recording start command and file name information together with information such as a recording start time to the recording apparatus 200. In that case, the recording apparatus 200 records information such as the recording start time in the additional information in addition to the file name information. After the start of processing in SR 702, in the recording apparatus 200, the digital audio signal generated and output by the analog front end 204 is processed by the digital signal processor 206 to sequentially generate audio data.

  The audio data generated by the recording device 200 is temporarily stored in the recording medium 208. At this time, confirmation of the remaining capacity of the recording medium 208 (free memory check) and storage area reservation processing when the free memory is insufficient are performed in SR704. Details of the processing in SR 704 will be described later. Here, processing after SR 706 will be described on the assumption that there is sufficient free memory.

  In SR706, the recording device 200 performs processing for recording audio data. That is, audio data sequentially generated by the digital signal processor 206 is stored in the recording medium 208. In subsequent SR708, the recording apparatus 200 transmits the audio data to the PC 300. For example, the audio data transmitted at this time is sequentially transmitted from the recording apparatus 200 to the PC 300 as blocks (packets) collected in a predetermined data size. Here, “sequential transmission” means that the recording device 200 stores the voice data therein and transmits it to the PC 300 at the same time.

  The PC 300 receives the audio data (data block) from the recording device 200 in SP706, and checks whether the received data block is complete (SP708). If it is complete, it is stored at SP 710, and a notification is transmitted to the recording apparatus 200 that the reception is complete at SP 712. On the other hand, when it is determined that the data block received at SP708 is incomplete, a notification that the reception is incomplete is transmitted to the recording apparatus 200 at SP712. On the recording device 200 side, when the notification from the PC 300 received in SR 710 is a notification that reception of the data block is incomplete, it is determined in SR 712 that transmission of the data block from the recording device 200 has failed, Proceed to SR714. Note that complete / incomplete reception of a data block can be detected by a known technique using an error detection code given to the data block.

  In SR714, which is a branch destination when it is determined in SR712 that the transmission of the data block has failed, the recording device 200 records the transmission failure. That is, the transmission failure information is recorded in the additional information described with reference to FIG. Specifically, information capable of specifying the data position where the transmission failure occurred is recorded in the transmission failure information TF in the file information chunk.

  If it is determined in SR712 that the transmission of the data block from the recording device 200 has been successful, the process proceeds to SR716. In SR716, the recording apparatus 200 determines whether or not there is an external input. There are two types of external inputs. The first type is an operation of the operation unit 212 by the user. The second type is a signal input from the PC 300 via the communication unit 218. While the determination in SR716 is denied, the processing from SR704 to SR716 is repeatedly performed in the recording apparatus 200. On the other hand, when the determination of SR716 is affirmed, the process proceeds to SR718.

  In SR 718, the recording apparatus 200 determines whether the external input is a user operation or a signal input from the PC 300. In the example shown in FIG. 7, it is assumed that a recording end command is output from the PC 300 while the recording device 200 is performing a recording operation.

  When the determination in SR 718 is affirmed, that is, in SR 720 which is a branch destination when it is determined that the external input is a user operation, the recording device 200 transmits operation information to the PC 300. The operation information is information including the contents of the user operation received by the operation unit 212. On the other hand, when the determination in SR 718 is negative, that is, in SR 722 that is a branch destination when it is determined that the external input is an input of a signal from the PC 300, a recording end process is performed. The recording end process includes a process of stopping the recording operation, a process of transmitting the last sound data (data block) to the PC 300 together with information indicating that the sound data is the last data. In the subsequent SR724, temporary audio file generation / storing processing is performed. That is, the process of storing the audio data recorded on the recording medium 208 in the data chunk, adding the additional information to generate a temporary audio file, and storing it in the recording medium 208 is performed in SR724.

  Processing performed by the PC 300 in relation to the processing of SR 716 to SR 720 described above in the recording apparatus 200 will be described. In SP716, the PC 300 determines whether or not the final data, that is, the last audio data has been received. If this determination is affirmed, the process proceeds to SP724, whereas if the determination is negative, the process proceeds to SP718.

  The processing when the determination in SP716 is denied will be described first. In SP718, the PC 300 determines whether or not operation information has been received. If the determination at SP 718 is negative, the process returns to SP 706, and the process of receiving audio data transmitted from the recording device 200 is continued. In SP720, which is a branch destination when the determination of SP718 is affirmed, the PC 300 analyzes the operation information received from the recording device 200. In the example shown in FIG. 7, it is assumed that the operation information transmitted from the recording device 200 performing the recording process is operation information for ending recording. That is, as a result of analysis by the processing in SP720, it is assumed that the operation information transmitted from the recording device 200 is determined to be related to the operation for ending recording.

  In step SP722, the PC 300 outputs a recording end command to the recording device 200, and then returns to step SP706. When viewed from the recording apparatus 200 side, the recording end command output in SP722 corresponds to the second type of external input received from the PC 300 via the communication unit 218. Based on this input, as described above, the determination of SR 716 is affirmed on the recording device 200 side, the determination of SR 718 is denied, and SR 722 and subsequent processing are performed.

  If the determination in SP716 is affirmed, the process proceeds to SP724, and the process for generating an audio file is performed in the PC 300. That is, the processing of storing audio data recorded in the auxiliary storage device 304 in a data chunk, adding additional information to generate a recording audio file, and storing it in the auxiliary storage device 304 is performed in SP724. The additional information can be generated inside the PC 300, but the additional information generated on the recording device 200 side may be added to the last audio data transmitted from the recording device 200 to the PC 300.

  By the way, the recording audio file generated by the PC 300 in SP724 is not necessarily a complete audio file. The reason is that there may be a failure in data transmission when audio data is sequentially transmitted from the recording device 200 to the PC 300. In preparation for this data transmission failure, the recording device 200 performs the determination process of SR726, and the processes of SR734 and SR736 are performed as necessary. Corresponding to these processes, the PC 300 performs the processes from SP726 to SP732. These processes will be described below.

  In SR726, the recording device 200 refers to the transmission failure information TF in the file information chunk and determines whether or not a transmission failure is recorded. If the determination in SR726 is affirmed, the process proceeds to SR734. If the determination is negative, the process proceeds to SR738.

  In SR734, which is a branch destination when the determination in SR726 is affirmed, the recording device 200 transmits an audio file transmission notification to the PC 300. In SR 736, the recording apparatus 200 transmits the temporary audio file stored in the recording medium 208 to the PC 300.

  Corresponding to the processing of SR734 and SR736 by the recording device 200, the processing from SP726 to SP732 is performed in the PC 300. In SP726, it is determined whether an audio file transmission notification is received from the recording apparatus 300. If the determination at SP726 is affirmative, the process proceeds to SP728, whereas if the determination is negative, the process proceeds to SP734. If the determination at SP 726 is negative, it means that the recording audio file stored in the PC 300 is complete. The reason is that the processing of SR734 and SR736 by the recording apparatus 200 is performed only when transmission failure is detected.

  In SP728, which is a branch destination when the determination of SP726 is affirmed, the PC 300 receives the temporary audio file transmitted by performing the processing of SR736 in the recording device 200. In the subsequent SP 730, the PC 300 performs a process of converting the temporary audio file received from the recording device 200 into a recording audio file. This process includes a process for renaming a file name, a process for updating additional information, and the like. In the present embodiment, as described above, both the temporary audio file and the recording audio file are recorded in the RIFF Wave format. However, when the temporary audio file and the recording audio file are recorded in different recording formats, the format conversion processing may be performed in SP730. The file name assigned to the recording audio file can be determined by referring to the file name information currently held by the PC 300. Alternatively, it can be determined with reference to the file information FI included in the temporary audio file.

  In SP732, the PC 300 deletes the recording audio file generated in SP724, and performs processing for making the recording audio file generated in SP730 the latest recording audio file.

  As described above, when the audio data transfer from the recording device 200 to the PC 300 fails due to the processing from SR 726 to SR 736 in the recording device 200 and the processing from SP 726 to SP 732 in the PC 300, the temporary audio is sent from the recording device 200 to the PC 300. An example of sending a file has been described. In this regard, it is also possible to do the following. That is, by referring to the transmission failure information TF, it is possible to know which data in the audio file is destroyed due to communication failure. With reference to the transmission failure information TF, only the necessary data block can be transmitted from the recording device 200 to the PC 300. In the PC 300, the data file received from the recording device 200 can be inserted into the audio data of the recording audio file to restore the audio file.

  By the way, it can be assumed that transmission / reception failure occurs when the audio file transmission process of SR736 is performed in the recording apparatus 200 and the audio file reception process is performed in the PC 300. Although the description of the processing in that case is omitted, it is possible to apply an error recovery processing procedure or the like in a generally used file transfer protocol.

  The recording audio file generated by the processing of SP724 or SP732 by the PC 300 is transmitted to the server 400. Hereinafter, a recording audio file transmission / reception process performed between the PC 300 and the server 400 will be described.

  In SP734, the PC 300 starts processing for transmitting the recording audio file to the server 400. In response to this processing, the server 400 side starts recording audio file reception processing in SS714.

  In SP736, the PC 300 monitors the communication status. In subsequent SP738, the PC 300 determines whether or not the communication with the server 400 has failed. If the determination at SP738 is affirmative, the process proceeds to SP740, whereas if the determination is negative, the process proceeds to SP746.

  In SP740, which is a branch destination when the determination in SP738 is affirmed, that is, when it is determined that communication between the PC300 and the server 400 has failed, the PC300 is for recording stored in the auxiliary storage device 304 of the PC300. Determine whether the audio file is incomplete. The determination processing of SP740 is processing in preparation for a case where some trouble occurs and the recording audio file stored in the auxiliary storage device 304 is destroyed or deleted.

  If the determination in SP740 is negative, the recording audio file stored in the auxiliary storage device 304 is complete, so the process returns to SP734 and the recording audio file is transmitted again from the beginning. On the other hand, if the determination in SP740 is affirmative, the recording audio file stored in the auxiliary storage device 304 is not complete, and thus the process proceeds to SP742, and the PC 300 transmits an audio file transfer request to the recording device 200.

  The recording apparatus 200 determines whether or not the audio file transfer request from the PC 300 has been received in SR738, and proceeds to SR740 if this determination is positive. On the other hand, if the determination in SR738 is negative, the process proceeds to SR744.

  In SR740, which is a branch destination when the determination in SR738 is affirmed, the recording device 200 performs an audio file search process. That is, the recording device 200 searches for an audio file in which the file name information included in the audio file request transmitted from the PC 300 is included in the file information FI among the audio files stored in the auxiliary storage device 304. The recording device 200 reads out the audio file searched in SR740 in SR742 and transmits it to the PC 300.

  In SP744, the PC 300 receives the audio file (temporary audio file) output from the recording device 200, and performs the same conversion process as the process in SP730 on the received audio file. Then, the process returns to SP734 and the audio file transmission process is performed again.

  When the determination in SP738 is negative, that is, in SP746, which is a branch destination when it is determined that communication with the server 400 has not failed, the PC 300 has completed transmission of the recording audio file to the server 400. Determine whether. If the determination at SP746 is affirmative, the process proceeds to SP748. On the other hand, if the determination of SP746 is negative, the process returns to SP736, and the audio file transmission process is continued.

  While the processing from SP734 to SP746 described above is performed by the PC 300, the server 400 repeatedly determines whether or not reception of the audio file is completed in SS716. If it is determined in SS716 that reception of the recording audio file transmitted from the PC 300 is completed (SS716: Yes), the process proceeds to SS718.

  In SS 718, the server 400 stores the recording audio file received from the PC 300 in the auxiliary storage device 430. When the storage process of the recording audio file in SS 718 is completed, the server 400 transmits an audio file storage completion notification to the PC 300 in SS 720, and a series of recording processes in the server 400 is completed.

  The PC 300 receives the audio file storage completion notification in SP748 and transfers the audio file storage completion notification to the recording device 200. The recording apparatus 200 receives the audio file storage completion notification transferred from the PC 300 at the SR 744, and uses the transmission completion information TC in the corresponding temporary audio file as information indicating that transmission of the audio file to the server 400 has been completed. rewrite.

  In SP750, the PC 300 performs a process of deleting the recording audio file stored in the auxiliary storage device 304 in SP750 even after the transmission to the server 400 is completed. Before performing the processing in SP750, the user is asked whether or not to delete the recording audio file from the auxiliary storage device 304, and the processing of SP750 is performed when the user performs an operation to delete the recording audio file. It may be.

  In SP752, the PC 300 corresponds to the temporary audio file stored in the recording medium 208 of the recording device 200 that is currently transmitted from the recording device 200 to the server 400 via the PC 300 and stored in the server 400. Ask the user if they want to erase things. If the determination in SP752 is affirmative, that is, if it is detected that the user has performed an operation to delete the temporary audio file, the process proceeds to SP754. In SP754, the PC 300 transmits a temporary audio file deletion command to the recording device 200. On the other hand, if the determination at SP752 is negative, the processing at SP754 is skipped. Then, a series of recording processing in the PC 300 is completed.

  The recording apparatus 200 determines in SR746 whether or not the temporary audio file deletion command has been received from the PC 300, and proceeds to SR748 if this determination is positive. In SR748, the recording apparatus 200 searches the recording medium 208 for a temporary audio file in which the file name information transmitted from the PC 300 together with the temporary audio file deletion command is included in the file information FI. Then, the found temporary audio file is deleted. Then, a series of recording processes in the recording apparatus 200 is completed.

  The flowcharts shown in FIGS. 7E and 7F are flowcharts for explaining the contents of the untransmitted data recovery process executed in SR 584, SP 586, and SS 586 in FIG. 5C.

  In SR770, the recording apparatus 200 determines whether there is uncompleted audio data. That is, during the recording process performed previously, the transfer and storage of the voice data (voice file) is completed due to a communication failure or a system failure occurring between the recording device 200 and the PC 300 or between the PC 300 and the server 400. The recording apparatus 200 determines whether there are any missing items. The determination process of SR770 is performed, for example, by reading the transmission completion information TC of the temporary audio file stored in the recording medium 208. If the determination in SR770 is affirmed, the process proceeds to SR772. If the determination is negative, the recording apparatus 200 completes the processes in FIGS. 7E and 7F and returns.

  In SR772, which is a branch destination when the determination of SR770 is affirmed, the recording apparatus 200 transmits a notification that there is untransmitted audio data to the PC 300. In the subsequent SR774, the user is notified that there is untransmitted audio data in the recording medium 208. As this notification method, voice, buzzer, etc., display by LED, display of characters, etc. on the display unit 216 are possible.

  The recording apparatus 200 transmits an audio file transmission notification to the PC 300 in SR776, and transmits a temporary audio file to the PC 300 in SR778.

  On the other hand, in PC 300, a determination is made in SP770 as to whether or not a notification that there is incomplete transmission data has been received from recording apparatus 200. If this determination is affirmative, the process proceeds to SP772. If the determination at SP770 is negative, the PC 300 completes the processing of FIGS. 7E and 7F and returns.

  In SP772, which is a branch destination when the determination in SP770 is affirmed, the PC 300 transfers a notification that there is untransmitted audio data to the server 400. In subsequent SP774, the PC 300 receives the audio file transmission notification transmitted from the recording device 200.

  In SP776, the PC 300 receives the temporary audio file transmitted from the recording device 200. In SP778, the PC 300 performs a process of converting the temporary audio file transmitted from the recording device 200 into a recording audio file. At this time, if the recording format is different between the temporary audio file and the recording audio file, processing for converting the recording format is performed. However, in this embodiment, as described above, both the temporary audio file and the recording audio file are recorded in the RIFF Wave format. Accordingly, in SP778, the process of renaming the file name of the temporary audio file is performed based on the file name information recorded in the file information FI in the temporary audio file received from the recording device 200.

  In SP780, the PC 300 stores the recording audio file in the auxiliary storage device 304. At this time, if a recording audio file with the same name already exists in the auxiliary storage device 304, it is overwritten and saved.

  In SS770, the server 400 determines whether or not a notification indicating that there is uncompleted audio data has been received from the PC 300. If this determination is affirmed, the process proceeds to SS772. If the determination of SS770 is negative, the server 400 completes the processing of FIGS. 7E and 7F and returns.

  In SP782, the PC 300 transmits an audio file transmission notification to the server 400. In subsequent SP784, the PC 300 transmits the recording audio file generated by performing the conversion process in SP778 to the server 400.

  In response to the processing of SP782 and SP784 described above being performed by the PC 300, the server 400 performs processing from SS772 to SS778 described below.

  In SS772, the server 400 receives the audio file transmission notification transmitted from the PC 300. In subsequent SS774, the server 400 receives the recording audio file transmitted from the PC 300. In SS776, the server 400 stores the recording audio file received from the PC 300 in SS774 in the auxiliary storage device 430. In SS 778, the server 400 transmits an audio file storage completion notification to the PC 300, completes the processing of FIGS. 7E and 7F, and returns.

  The PC 300 receives the audio file storage completion notification in SP786 and transfers this notification to the recording device 200. The recording apparatus 200 receives this notification at SR780, and rewrites the transmission completion information TC of the temporary audio file transmitted to the PC 300 by the process of SR778 to clear the unsent record at S782.

  In SP788, the PC 300 deletes the recording audio file transmitted to the server 400 in the processing of SP784 from the auxiliary storage device 304. Note that the recording audio file in the auxiliary storage device 304 may be configured so that the user can select storage / erasure of the recording audio file instead of erasing as described above.

  In step SP790, the PC 300 determines whether or not to delete the temporary audio file stored in the recording device 200. Here, the temporary audio file to be erased is a temporary audio file transmitted from the recording device 200 to the PC 300 in the process of SR778. As the determination processing in SP790, for example, after the recording audio file is transferred and stored in the server 400, the result of the user setting an option as to whether or not to delete the temporary audio file in the recording device 200 is referred to. It is possible. Alternatively, it is possible to detect a user operation by displaying on the display unit 314 such as “Do you want to delete the audio file in the recording device? (Y / N)”.

  If it is determined in SP 790 that the user wants to delete the temporary audio file, the process proceeds to SP 792, while if it is determined that the user does not want to delete the temporary audio file, the PC 300 performs FIG. The process of 7F is completed and the process returns.

  In SP792, the PC 300 transmits a temporary audio file deletion command to the recording device 200, completes the processes in FIGS. 7E and 7F, and returns.

  The recording apparatus 200 receives the temporary audio file deletion command transmitted from the PC 300 at SR784, performs the process of deleting the temporary audio file transmitted to the PC300 at SR778 in S786, and completes the processes of FIGS. 7E and 7F. Return.

  The flowchart shown in FIG. 7G is a flowchart for explaining the contents of the free memory confirmation / reservation process executed by the recording apparatus 200 in SR 704 in FIG. 7A. In SR790, the recording apparatus 200 acquires the free space information of the recording medium 208 and determines whether the free space exceeds a predetermined amount (whether there is sufficient free space). If the determination in SR790 is affirmed, the recording apparatus 200 completes the process shown in FIG. 7G and returns.

  In SR 792, which is a branch destination when the determination in SR 790 is denied, the recording device 200 checks whether there is any erasable temporary audio file stored in the recording medium 208. Specifically, the recording device 200 reads the additional information of the temporary audio file stored in the recording medium 208, and information indicating that the transmission of the audio file to the server 400 is completed in the transmission completion information TC. Searches for a written temporary audio file.

  Based on the processing result in SR792, the recording apparatus 200 determines in SR794 whether or not there is a file that has been stored in the server. If the determination in SR794 is affirmed, the process proceeds to SR796. If the determination is negative, the process proceeds to SR798.

  In SR796 that is a branch destination when the determination in SR794 is affirmed, the recording apparatus 200 completes the process of transferring and saving to the server 400 in the temporary audio file saved in the recording medium 208. Delete the existing file. At this time, there may be a plurality of temporary audio files that can be deleted. In such a case, the temporary audio file with the oldest time stamp may be deleted, or the temporary audio file with the largest capacity may be deleted. Alternatively, the temporary audio file with the smallest capacity may be deleted. It is also possible to leave the temporary audio file to be deleted to the user's selection. When deleting the temporary audio file, the user may be notified by a warning sound or the like. Further, when the temporary audio file is deleted from the recording medium 208, the temporary audio file may be transmitted to the PC 300 and temporarily stored in the auxiliary storage device 304.

  In SR798, which is a branch destination when the determination in SR794 is denied, the recording device 200 performs a process of notifying the user of a warning of insufficient memory capacity. As the warning notification, it is possible to emit a sound, but it is also possible to perform a warning notification by display such as blinking the entire display of the display unit 216. Then, when the remaining memory capacity runs out, a process for forcibly stopping the recording process in the recording device 200 and the PC 300 is performed. Alternatively, following the process of SR798, the temporary audio file stored in the recording medium 208 is temporarily transferred to the auxiliary storage device 304 of the PC 300, and the process for ensuring the remaining capacity of the recording medium 208 is performed. This process may be performed continuously.

  After the processing of SR796 or SR798 described above, the recording apparatus 200 completes the processing of FIG. 7G and returns.

  The outline of the recording process performed by the recording apparatus 200, the PC 300, and the server 400 described above with reference to the flowchart of FIG. 7 will be described with reference to FIG. FIG. 8 shows a typical state in which the recording device 200, the PC 300, and the server 400 are connected to be communicable with each other, and information, data, files, and the like exchanged between the three parties.

  The recording apparatus 200 and the PC 300 are connected to each other through communication units 218 and 302 so that bidirectional communication is possible. The PC 300 is connected to the network NW via the communication unit 302, and the server 400 is also connected to the network NW via the network interface 420. As a result, the PC 300 and the server 400 are connected via the network NW so that bidirectional communication is possible.

  When the user of the recording apparatus 200 performs a recording start operation, the operation information is transmitted from the recording apparatus 200 to the PC 300, and the PC 300 transmits a recording start notification to the server 400. Then, the server 400 issues file name information and transmits the file name information to the PC 300. The PC 300 transmits file name information and a recording start command to the recording device 200.

  The recording apparatus 200 performs a recording operation, and the sound data is stored in the recording apparatus 200 and simultaneously transferred to the PC 300 at the same time. At this time, a notification notifying whether the transmission of the audio data from the recording apparatus 200 to the PC 300 is successful or unsuccessful is transmitted from the PC 300 to the recording apparatus 200. If the transmission of the audio data fails, the recording apparatus 200 has failed in transmission. Is recorded. When the recording operation is completed and the last audio data is transmitted from the recording device 200 to the PC 300, a recording audio file is generated in the PC 300. The recording audio file is given a file name based on the file name information transmitted from the server 400.

  On the other hand, the recording device 200 also generates a temporary audio file when the recording operation is finished. File name information is recorded in the file information FI in the additional information in the temporary audio file. When a failure is detected in the sequential transfer of audio data from the recording device 200 to the PC 300, a temporary audio file is transmitted from the recording device 200 to the PC 300. If there is no failure in the exchange of audio data between the recording device 200 and the PC 300, the PC 300 transmits the recording audio file generated in the PC 300 to the server 400. On the other hand, if a failure is detected when audio data is exchanged between the recording device 200 and the PC 300, the PC 300 converts the temporary audio file transmitted from the recording device 200 into a recording audio file and transmits the recording audio file to the server 400. .

  If there is a failure in sending the recording audio file from the PC 300 to the server 400, the PC 300 detects it. In this case, the recording audio file stored in the PC 300 is retransmitted to the server 400. Here, when it is detected that the recording audio file stored in the PC 300 is incomplete for some reason, the PC 300 transmits an audio file transfer request to the recording device 200.

  The recording device 200 searches the recording medium 208 for an audio file in which the file name information included in the audio file transfer request is recorded in the file name information FI in the additional information, and searches the PC 300 for the corresponding temporary audio file. Send. The PC 300 converts the temporary audio file into a recording audio file and transmits it to the server 400.

  The example in which the file name information is issued by the server 400 when the recording start notification is transmitted from the PC 300 that has received the operation information from the recording device 200 to the server 400 has been described. The file name information does not necessarily match the file name of the audio file stored in the server 400. For example, some identification information may be issued by the server 400, and the identification information may be recorded in the additional information of the audio file. With this identification information, the recording device 200, the PC 300, and the server 400 can identify the audio file without referring to the file name. In this case, the issuer of the identification information is not limited to the server 400, but may be the PC 300 or the recording device 200. In short, identification information that can be commonly recognized among the recording device 200, the PC 300, and the server 400 is determined by any one of the recording device 200, the PC 300, and the server 400, and the identification information is the additional information in the audio file. It only has to be recorded inside. However, since the server 400 may be connected to a plurality of PCs, it is necessary to avoid duplication of identification information. For this purpose, a numeric string or character string that can be used in correspondence with the combination of each recording device 200 and PC 300 is allocated, and the identification information is obtained by appropriately adding a branch number or a code to the numeric string or character string. It is possible.

  FIG. 9 is a diagram illustrating an example in which recording apparatus 200A includes communication unit 218A including first communication unit 218A-1 and second communication unit 218A-2 as a modification of the embodiment of the present invention. .

  The recording device 200A and the PC 300 are connected via the communication units 218A-1 and 302 so that bidirectional communication is possible. The PC 300 is connected to the network NW via the communication unit 302, and the server 400 is also connected to the network NW via the network interface 420. As a result, the PC 300 and the server 400 are connected via the network NW so that bidirectional communication is possible. In addition to the above, the recording apparatus 200A is configured to be connectable to the network NW via the communication unit 218A-2. The communication unit 218A-2 can be configured to be connectable to a wireless communication network such as a public wireless network or a public wireless telephone network. Alternatively, the communication unit 218A-2 may be configured to be connectable to the network NW via a wireless LAN or the like. With the configuration described above, the recording apparatus 200A can be connected to the server 400 as necessary in addition to being connected to the PC 300.

  In the recording system having the above-described configuration, the recording operation of the recording apparatus 200A is started and completed, and the same processing as described with reference to FIG. 8 is performed until the recording audio file is generated in the PC 300. . That is, when the user of the recording device 200A performs a recording start operation, operation information is transmitted from the recording device 200A to the PC 300, and a recording start notification is transmitted from the PC 300 to the server 400. The server 400 issues file name information and transmits the file name information to the PC 300. The PC 300 transmits file name information and a recording start command to the recording device 200A.

  The recording device 200A that has received the recording start command from the PC 300 starts the recording operation, accumulates the audio data in the recording device 200A, and simultaneously transfers them to the PC 300 at the same time. At this time, a notification notifying whether the transmission of audio data from the recording apparatus 200A to the PC 300 is successful or unsuccessful is transmitted from the PC 300 to the recording apparatus 200A. If the transmission of the audio data fails, the recording apparatus 200A has failed in transmission. Is recorded. When the recording operation ends and the last sound data is transmitted from the recording device 200A to the PC 300, a recording sound file is generated in the PC 300. The recording audio file is given a file name based on the file name information transmitted from the server 400.

  On the other hand, the recording device 200A also generates a temporary audio file when the recording operation is finished. File name information is recorded in the file information FI in the additional information in the temporary audio file.

  When a communication failure between the recording device 200 </ b> A and the PC 300 is not detected, the recording audio file generated by the PC 300 is transmitted from the PC 300 to the server 400. On the other hand, when a communication failure occurs during transmission of audio data from the recording apparatus 200A to the PC 300 or transmission of a recording audio file from the PC 300 to the server 400, the recording apparatus 200A to the server 400 will be described below. The audio data file is transmitted. This point is different from that described with reference to FIGS.

  If a failure is detected when transferring the audio data from the recording device 200A to the PC 300, the recording device 200A transmits the audio file generated when recording is completed and stored in the recording medium 208 via the communication unit 218A-2. Send directly to server 400. The audio file transmitted at this time may be a temporary audio file or may be a recording audio file generated by performing a conversion process in the recording apparatus 200A. When a temporary audio file is transmitted from the recording device 200A to the server 400, processing for conversion into a recording audio file is performed in the server 400. When the audio file is transmitted from the recording device 200A to the server 400 and the storage of the audio file in the server 400 is completed, a file deletion command is output from the recording device 200A to the PC 300. When the PC 300 receives this file deletion command, it deletes the recording audio file stored in the auxiliary storage device 304. The erased audio file for recording is an incomplete audio file because communication failed between the recording device 200A and the PC 300. Further, in the application program executed on the PC 300, if the temporary audio file in the recording device 200A is set to be deleted after the storage of the audio file is completed in the server 400, the recording in the recording device 200A is performed. The corresponding temporary audio file is deleted.

  When a failure is detected when the recording audio file is transmitted from the PC 300 to the server 400 (corresponding to SP738: “Yes” in FIG. 7C), and the audio file stored in the PC 300 is incomplete. In some cases (SP740: equivalent to “Yes” determination), the PC 300 outputs an audio file transfer request to the recording device 200A. The recording apparatus 200A receives the audio file transfer request from the PC 300, searches for the corresponding audio file from the recording medium 208, and transmits it to the server 400 via the communication unit 218A-2. The audio file transmitted at this time may be a temporary audio file or may be a recording audio file generated by performing a conversion process in the recording apparatus 200A. When a temporary audio file is transmitted from the recording device 200A to the server 400, processing for conversion into a recording audio file is performed in the server 400.

  After storing the recording audio file in the auxiliary storage device 430, the server 400 transmits an audio file storage completion notification to the PC 300. This audio file storage completion notification is transferred from the PC 300 to the recording device 200A. Alternatively, the audio file storage completion notification may be transmitted from the server 400 to both the PC 300 and the recording device 200A. The recording apparatus 200A rewrites the transmission completion information TC in the additional information in the temporary audio file from “untransmitted” to “transmitted” (corresponding to the process of SR780 in FIG. 7F). On the other hand, in the PC 300, the processing from SP788 to SP792 shown in FIG. 7F is performed, and the recording audio file (which is a broken audio file) stored in the PC 300 is deleted. Then, a temporary file deletion command is transmitted to the recording apparatus 200A according to the user setting (equivalent to the determination of SP790: “Yes”). The recording apparatus 200A deletes the temporary audio file specified by the temporary audio file deletion command.

  In addition to the above processing, when the recording device 200A is turned on, the presence of uncompleted audio data is determined (corresponding to the determination of SR770 in FIG. 7E: “Yes”). An audio file can be transmitted from the recording apparatus 200A to the server 400 via the unit 218A-1.

  In the example described with reference to FIG. 9, the recording apparatus 200A includes a communication unit 218A-1 and a communication unit 218A-2. The audio data is transmitted from the recording device 200A to the PC 300 through the communication unit 218A-1. On the other hand, when a transmission error occurs between the recording device 200A and the PC 300 or between the PC 300 and the server 400, the audio file is bypass-transferred to the server 400 via the communication unit 218A-2. Therefore, even if any communication failure occurs between the recording device 200A and the PC 300 or between the PC 300 and the server 400, the audio file can be transmitted to the server 400 via the bypass route.

  In the above description, an example in which information is transmitted / received between the recording device 200 (200A) and the server 400 via the PC 300 has been described. However, the recording device 200 (200A) itself is provided in the PC 300. It is possible to have a configuration including functions.

  For example, if the recording device has a configuration such as a smartphone and is configured to be directly connectable to the server, the following recording processing can be performed between the two. That is, when the user operates the recording device to connect to the server and performs an authentication operation to establish a connection with the server, the recording device can be operated.

  When the recording device is operated, operation information is output to the server, and an operation command is output from the server to the recording device. When the user performs a recording start operation, operation information is output from the recording device to the server. File name information is output from the server to the recording device together with a recording operation command. This file name information is information that can specify the file name determined to be given to the audio file when the audio file is stored in the server. As the recording operation proceeds, audio data is sequentially transferred from the recording device to the server. At this time, if there is an information communication failure, the information communication failure is detected and recorded by the recording device or the server. When the user performs an operation to stop the recording operation, the operation information is output to the server, and a recording operation stop command is output from the server to the recording device.

  The recording device outputs the last audio data to the server and generates a temporary audio file in the recording device. File name information is recorded in the additional information in the temporary audio file. On the server side, when the last audio data is received from the recording device, an audio file is generated. The audio file generated at this time is given the previously determined file name.

  When the information communication failure is detected by the recording device or the server, a temporary audio file stored in the recording device is transmitted to the server. At this time, the recording device may convert the temporary audio file into a recording audio file, give a file name based on the file name information, and transmit the file to the server. Alternatively, a temporary audio file may be transmitted from the recording device to the server, the temporary audio file may be converted into a recording audio file on the server side, and the previously determined file name may be assigned.

  As described above, the audio files recorded and generated by the recording apparatus 200 (200A) are automatically transferred to the server 400 as an external processing apparatus, and are collected and recorded. It becomes easy. At this time, even if a communication failure or the like occurs, backup can be performed by the temporary audio file stored on the recording device 200 (200A) side, and more reliable transfer of the audio file can be expected.

  In the above, an example in which a recording operation is performed by the recording device 200 (200A) for recording sound and the generated sound files are collected in the server 400 has been described. However, instead of the recording device 200 (200A), a data logger, Data collection and imaging are performed by an imaging device or the like, and generated data files and image files can be collected in the server 400.

  Next, other characteristic technical matters of the present application are appended as follows.

[Additional notes]
1. A microphone for voice input,
An audio storage processing unit that processes an audio signal output from the microphone to generate digital audio data, generates a first audio file storing the audio data, and stores the first audio file in a recording medium;
A communication unit capable of communicating with an external processing device;
A voice data transmission processing unit that sequentially transmits the voice data generated by the voice storage processing unit simultaneously with a recording operation to the external processing device via the communication unit;
An incomplete notification reception processing unit that receives an incomplete notification issued from the external processing device when it is detected that reception of the sequentially transmitted audio data is incomplete in the external processing device;
An audio file read processing unit that reads out the first audio file including the audio data that has received the incomplete reception notification from the recording medium when the incomplete notification is received;
A recording apparatus comprising: an audio file transmission processing unit configured to transmit the first audio file read by the audio file reading processing unit to the external processing device via the communication unit.

2. In performing the recording operation, the information processing apparatus further includes an identification information reception processing unit that receives the identification information transmitted from the external processing device via the communication unit,
The voice storage processing unit records the voice data with the identification information added when the first voice file is generated,
The recording apparatus according to claim 1, wherein the audio file reading processing unit reads the first audio file to which the identification information is added from the recording medium.

3. The identification information is a file name given to the second audio file storing the audio data in the external processing device,
The voice storage processing unit stores the voice data and stores the first voice file having the file name,
The recording apparatus according to claim 2, wherein the audio file reading processing unit reads the first audio file having the file name included in the incomplete notification from the recording medium.

4). A microphone for voice input,
An audio storage processing unit that processes an audio signal output from the microphone to generate digital audio data, generates a first audio file storing the audio data, and stores the first audio file in a recording medium;
A communication unit capable of communicating with an external processing device and a second external processing device different from the external processing device;
A voice data transmission processing unit that sequentially transmits the voice data generated by the voice storage processing unit simultaneously with a recording operation to the external processing device via the communication unit;
An incomplete notification reception processing unit that receives an incomplete notification issued from the external processing device when it is detected that reception of the sequentially transmitted audio data is incomplete in the external processing device;
An audio file read processing unit that reads out the first audio file including the audio data that has received the incomplete reception notification from the recording medium when the incomplete notification is received;
A recording apparatus comprising: an audio file transmission processing unit configured to transmit the first audio file read by the audio file reading processing unit to the second external processing device via the communication unit.

  According to the recording device of the supplementary item 4, when it is detected that the reception of the sequentially transmitted sound data is incomplete in the external processing device, the first sound including the sequentially transmitted sound data The file is transmitted from the recording device to the second external processing device. Therefore, even if there is a failure in communication between the recording device and the external processing device or between the external processing device and the second external processing device, the second external processing device includes the first data including the audio data. Audio files can be received.

5. The communication unit includes a first communication unit capable of communicating with the external processing device, and a second communication unit capable of communicating with the second external processing device,
The recording device according to claim 4, wherein the audio file transmission processing unit transmits the first audio file to the second external processing device via the second communication unit.

  According to the recording device described in appendix 5, even if a communication failure occurs between the recording device and the external processing device, the recording device and the second external processing device perform the second communication. The second external processing device can receive the first audio file including complete audio data from the recording device.

  6). The recording device according to any one of additional items 1 to 5, wherein the communication unit is configured to be communicable in a wireless form.

  According to the recording device described in the supplementary item 6, when the user who wears the recording device moves to a position away from the external processing device, there is no problem such as entanglement of the code.

7). A microphone for voice input,
An audio storage processing unit that processes an audio signal output from the microphone to generate digital audio data, generates a first audio file storing the audio data, and stores the first audio file in a recording medium;
A communication unit capable of communicating with an external processing device;
A voice data transmission processing unit that sequentially transmits the voice data generated by the voice storage processing unit simultaneously with a recording operation to the external processing device via the communication unit;
A communication failure detection unit that detects a failure in the information communication when there is a failure in the sequential transmission of the audio data with the external processing device;
An audio file read processing unit that reads out from the recording medium a first audio file that includes audio data that has failed in the sequential transmission when the communication failure detection unit detects the failure in the sequential transmission;
A recording apparatus comprising: an audio file transmission processing unit configured to transmit the first audio file read by the audio file reading processing unit to the external processing device via the communication unit.

  According to the recording device according to attachment 7, the first audio file including the audio data that has failed in the sequential transmission of the audio data is detected by the recording device, and the audio data that has failed to be transmitted is read by the audio file reading processing unit. And transmitted to the external processing apparatus via the communication unit. Therefore, even if a failure occurs in the sequential transmission of the audio data between the recording device and the external processing device, the loss of the audio data can be prevented.

8). In performing the recording operation, the information processing apparatus further includes an identification information reception processing unit that receives the identification information transmitted from the external processing device via the communication unit,
The voice storage processing unit adds the identification information to the voice data when generating the first voice file,
The recording apparatus according to appendix 7, wherein the audio file read processing unit reads the first audio file to which the identification information is added from the recording medium.

  According to the recording device according to attachment 8, the identification information transmitted from the external processing device is added to the first sound file generated in the recording device. Therefore, it is possible to identify the audio file by the identification information, and it is possible to suppress transmission of an incorrect file.

9. The identification information is a file name given to a second audio file that stores the audio data in the external processing device that has received the audio data,
The voice storage processing unit stores the voice data and stores the first voice file having the file name;
9. The recording apparatus according to claim 8, wherein the audio file read processing unit reads a first audio file having the file name from the recording medium.

  According to the recording device according to attachment 9, since the file name given when being saved as the second audio file by the external processing device is added, the audio file saved by the external processing device and the recording are recorded. Correspondence with an audio file stored on the apparatus side is facilitated.

  10. The recording apparatus according to any one of appendices 7 to 9, wherein the communication unit is configured to be able to communicate wirelessly.

  According to the recording device described in the additional item 10, there is no problem that a user who wears the recording device moves around to a position away from the external processing device, such as a cord entangled.

11. A microphone for voice input,
An audio storage processing unit that processes an audio signal output from the microphone to generate digital audio data, generates a first audio file storing the audio data, and stores the first audio file in a recording medium;
A communication unit capable of communicating with an external processing device and a second external processing device different from the external processing device;
A voice data transmission processing unit that sequentially transmits the voice data generated by the voice storage processing unit simultaneously with a recording operation to the external processing device via the communication unit;
A communication failure detection unit that detects a failure in the information communication when there is a failure in the sequential transmission of the audio data with the external processing device;
An audio file read processing unit that reads out from the recording medium a first audio file that includes audio data that has failed in the sequential transmission when the communication failure detection unit detects the failure in the sequential transmission;
A recording apparatus comprising: an audio file transmission processing unit configured to transmit the first audio file read by the audio file reading processing unit to the second external processing device via the communication unit.

  According to the recording device according to attachment 11, when the sequential transmission of the audio data fails, the first audio file that is detected on the recording device side and includes the audio data that has failed to be transmitted is an audio file read processing unit. Is transmitted to the external processing device via the communication unit. Therefore, even if a failure occurs in the sequential transmission of the audio data between the recording device and the external processing device, the loss of the audio data can be prevented.

12 The communication unit includes a first communication unit capable of communicating with the external processing device, and a second communication unit capable of communicating with the second external processing device,
12. The recording device according to claim 11, wherein the audio file transmission processing unit transmits the first audio file to the second external processing device via the second communication unit.

  According to the recording device according to attachment 12, even if a communication failure occurs between the recording device and the external processing device, the recording device and the second external processing device perform the second communication. The second external processing device can receive the first audio file including the audio data from the recording device.

  13. 13. The recording apparatus according to claim 11 or 12, wherein the communication unit is configured to be communicable in a wireless form.

  According to the recording device described in the supplementary item 13, when the user who wears the recording device moves to a position away from the external processing device, a problem such as a tangled line does not occur.

14 A recording system comprising a recording device and an external processing device capable of communicating with the recording device,
The recording device is
A microphone for voice input,
An audio storage processing unit that processes an audio signal output from the microphone to generate digital audio data, generates a first audio file storing the audio data, and stores the first audio file in a recording medium;
A first communication unit capable of communicating with the external processing device;
A voice data transmission processing unit that sequentially transmits the voice data generated by the voice storage processing unit simultaneously with a recording operation to the external processing device via the first communication unit;
When the external processing device detects that reception of the sequentially transmitted audio data is incomplete, the external processing device is configured to receive an incomplete notification from the external processing device via the first communication unit. A complete notification reception processing unit;
An audio file read processing unit that reads out the first audio file including the audio data that has received the incomplete reception notification from the recording medium when the incomplete notification is received;
A first audio file transmission processor that transmits the first audio file read by the audio file read processor to the external processing device via the first communication unit;
The external processing device is
A second communication unit capable of communicating with the recording device;
A third communication unit capable of communicating with a second external processing device different from the external processing device;
An audio data reception processing unit that receives the audio data sequentially transmitted from the recording device via the second communication unit;
An audio file generation processing unit that generates a second audio file that is an audio file storing the audio data received by the audio data reception processing unit;
A second audio file transmission processing unit that transmits the second audio file to the second external processing device via the third communication unit;
The failure is detected when the second audio file is transmitted from the external processing device to the second external processing device, and the second audio file is determined to be incomplete. An incomplete notification output unit for issuing a notification to the recording device via the second communication unit;
An audio file reception processing unit that receives the first audio file transmitted from the recording device that has received the incomplete notification via the second communication unit;
The second audio file transmission processing unit uses the first audio file received by the audio file reception processing unit as the second audio file when the information communication failure is detected as the third audio file. A recording system for transmitting to the second external processing device via a communication unit.

  According to the recording system according to attachment 14, when the failure of information communication is detected by the external processing device, the first sound including information that may not be successfully transmitted / received due to the failure of information communication The file is read by the audio file read processing unit of the recording device and transmitted to the external processing device via the first communication unit. The first audio file is transmitted from the external processing device to the second external processing device as a second audio file. Therefore, even if the external processing device fails to transmit the second audio file, or the second audio file generated in the external processing device has a defect, a sound file having no defect is It becomes possible to retransmit to the external processing device, and it is possible to prevent the loss of the voice data.

15. The external processing device further includes
A first identification information reception processing unit for receiving identification information transmitted from the second external processing device via the third communication unit;
An identification information transmission processing unit that transmits the identification information to the recording device via the second communication unit;
The recording device further includes:
A second identification information reception processing unit that receives the identification information transmitted from the external processing device via the first communication unit;
In the recording device,
The voice storage processing unit adds the identification information to the voice data when generating the first voice file,
The audio file read processing unit reads the first audio file to which the identification information is added from the recording medium,
In the external processing device,
The second audio file transmission processing unit receives the first audio file added with the identification information received by the audio file reception processing unit as the second audio file via the third communication unit. 15. The recording system according to appendix 14, wherein the recording system is transmitted to the second external processing device.

  According to the recording system according to attachment 15, the identification information transmitted from the second external processing device to the recording device via the external processing device is added to the first audio file generated in the recording device. . Therefore, the identification information ensures the correspondence between the first audio file stored in the recording device and the audio file required on the second external processing device side, and an incorrect file is transmitted. Can be suppressed.

16. The identification information includes file name information that is information that can identify a file name assigned from the second external processing device,
In the recording device,
The voice storage processing unit stores the first voice file to which the file name information is added,
The audio file read processing unit reads the first audio file to which the file name information is added from the recording medium,
In the external processing device,
The second audio file transmission processing unit adds the file name assigned by the second external processing device to the first audio file to which the file name information is added and received by the audio file reception processing unit. 16. The recording system according to claim 15, wherein the recording system is provided and transmitted as the second audio file to the second external processing device via the third communication unit.

  According to the recording system of appendix 16, in the recording device, file name information, which is information that can identify the file name assigned by the second external processing device, is added, and the audio data becomes the first audio file. Since it is recorded, it becomes easy to associate the first audio file stored on the recording device side with the second audio file required on the second external processing device side.

17. A recording system comprising a recording device and an external processing device capable of communicating with the recording device,
The recording device is
A microphone for voice input,
An audio storage processing unit that processes an audio signal output from the microphone to generate digital audio data, generates a first audio file storing the audio data, and stores the first audio file in a recording medium;
A first communication unit capable of communicating with the external processing device;
A second communication unit capable of communicating with a second external processing device different from the external processing device;
A voice data transmission processing unit that sequentially transmits the voice data generated by the voice storage processing unit simultaneously with a recording operation to the external processing device via the first communication unit;
A non-transmission from the external processing device when a failure in transmission of the second audio file including the audio data sequentially transmitted from the external processing device to the second external processing device is detected. An incomplete notification reception processing unit for receiving a complete notification via the first communication unit;
An audio file read processing unit that reads out the first audio file including the audio data that has received the notification of the transmission failure when the incomplete notification is received;
A second audio file transmission processor that transmits the first audio file read by the audio file read processor to the second external processing device via the second communication unit;
The external processing device is
A third communication unit capable of communicating with the recording device;
A fourth communication unit capable of communicating with the second external processing device;
An audio data reception processing unit that receives the audio data sequentially transmitted from the recording device via the third communication unit;
An audio file generation processing unit for generating the second audio file storing the audio data received by the audio data reception processing unit;
A third audio file transmission processing unit that transmits the second audio file to the second external processing device via the fourth communication unit;
When the transmission failure of the second audio file from the external processing device to the second external processing device is detected, the incomplete notification is issued to the recording device via the third communication unit. A recording system comprising an incomplete notification output unit.

  According to the recording system according to attachment 17, the second audio file including the audio data sequentially transmitted to the external device via the first communication unit is transmitted from the external device to the second external device. When the failure is detected, the first audio file including the audio data that has not been transmitted correctly due to the failure is read out by the audio file reading processing unit of the recording device, and is transmitted via the second communication unit. Sent directly to the second external processing device. Therefore, even if there is a failure in communication between the recording device and the external processing device, or between the external processing device and the second external processing device, the second external processing device can store the first audio file. It becomes possible to receive.

18. The recording system according to item 17, wherein the second communication unit is the same as the first communication unit.

  According to the recording system of appendix 18, the recording device and the second external processing device can be used even when a communication failure occurs between the external processing device and the second external processing device. Communication is possible, and the second external processing device can receive the first audio file from the recording device.

  19. 19. The recording system according to claim 14, wherein the first and second communication units are configured to be communicable in a wireless form.

  According to the recording system described in the supplementary item 19, when the user who wears the recording apparatus moves to a position away from the external processing apparatus, a problem such as a tangled line does not occur.

20. A recording system comprising a recording device and an external processing device capable of communicating with the recording device,
The recording device is
A microphone for voice input,
An audio storage processing unit that processes an audio signal output from the microphone to generate digital audio data, generates a first audio file storing the audio data, and stores the first audio file in a recording medium;
A first communication unit capable of communicating with the external processing device;
An operation unit for receiving a user operation for designating an operation of the recording device;
An operation information transmission processing unit for transmitting operation information including the content of the user operation received in the operation unit to the external processing device via the first communication unit;
An operation command reception processing unit that receives an operation command transmitted from the external processing device in response to the received operation information via the first communication unit;
An operation command execution unit that controls the recording device to perform an operation corresponding to the operation command received via the first communication unit;
The external processing device is
A second communication unit capable of communicating with the recording device;
An operation command transmission processing unit for outputting an operation command corresponding to the operation information received via the second communication unit to the recording device via the second communication unit; system.

According to the recording system described in appendix 20,
Since the recording device operates based on the operation command transmitted from the external processing device to the recording device based on the operation information transmitted from the recording device to the external processing device, the linking operation between the recording device and the external processing device is more reliable. Can be performed.

21. The recording device further includes:
Simultaneously with the recording operation based on the operation command, an audio data transmission processing unit that sequentially transmits the audio data generated by the audio storage processing unit to the external processing device via the first communication unit;
An incomplete notification reception processing unit that receives an incomplete notification issued from the external processing device when it is detected that reception of the sequentially transmitted audio data is incomplete in the external processing device;
An audio file read processing unit that reads out the first audio file including the audio data that has received the incomplete reception notification from the recording medium when the incomplete notification is received;
A first audio file transmission processor that transmits the first audio file read by the audio file read processor to the external processing device via the first communication unit;
The external processing device further includes
A third communication unit capable of communicating with a second external processing device different from the external processing device;
An audio data reception processing unit that receives the audio data sequentially transmitted from the recording device via the second communication unit;
An audio file generation processing unit that generates a second audio file that is an audio file storing the audio data received by the audio data reception processing unit;
A second audio file transmission processing unit that transmits the second audio file to the second external processing device via the third communication unit;
When a failure is detected during transmission of the second audio file from the external processing device to the second external processing device, the incomplete notification is issued to the recording device via the second communication unit. An incomplete notification output section;
An audio file reception processing unit that receives the first audio file transmitted from the recording device that has received the incomplete notification via the second communication unit;
In the external processing device,
The second audio file transmission processing unit uses the first audio file received by the audio file reception processing unit as the second audio file when the information communication failure is detected as the third audio file. Item 22. The recording system according to Item 20, wherein the recording system transmits the information to the second external processing device via the communication unit.

  According to the recording system according to attachment 21, when the information processing failure is detected by the external processing device, the first sound including information that may not be successfully transmitted and received due to the information communication failure. The file is read by the audio file read processing unit of the recording device and transmitted to the external processing device via the first communication unit. The first audio file is transmitted from the external processing device to the second external processing device as a second audio file. Therefore, even if the external processing device fails to transmit the second audio file, or the second audio file generated in the external processing device has a defect, a sound file having no defect is It becomes possible to retransmit to the external processing device, and it is possible to prevent the loss of the voice data.

22. The external processing device further includes
A first identification information reception processing unit for receiving identification information transmitted from the second external processing device via the third communication unit;
An identification information transmission processing unit that transmits the identification information to the recording device via the second communication unit;
The recording device further includes:
A second identification information reception processing unit that receives the identification information transmitted from the external processing device via the first communication unit;
In the recording device,
The voice storage processing unit adds the identification information to the voice data when generating the first voice file,
The audio file read processing unit reads the first audio file to which the identification information is added from the recording medium,
In the external processing device,
The second audio file transmission processing unit receives the first audio file added with the identification information received by the audio file reception processing unit as the second audio file via the third communication unit. Item 22. The recording system according to Item 21, wherein the recording system is transmitted to the second external processing device.

  According to the recording system described in attachment 22, the identification information transmitted from the second external processing device to the recording device via the external processing device is added to the first audio file generated in the recording device. . For this reason, the added identification information ensures the correspondence between the first audio file stored in the recording device and the audio file required on the second external processing device side, and an incorrect file is transmitted. It can be suppressed.

23. The identification information includes file name information that is information that can identify a file name assigned from the second external processing device,
In the recording device,
The voice storage processing unit stores the first voice file to which the file name information is added,
The audio file read processing unit reads the first audio file to which the file name information is added from the recording medium,
In the external processing device,
The second audio file transmission processing unit assigns the file name assigned by the second external processing device to the first audio file to which the file name information received by the audio file reception processing unit is added. The recording system according to Item 22, wherein the recording system transmits the second audio file to the second external processing device via the third communication unit.

  According to the recording system according to attachment 23, in the recording device, file name information, which is information that can identify the file name assigned by the second external processing device, is added, and the audio data becomes the first audio file. Since it is recorded, it becomes easy to associate the first audio file stored on the recording device side with the second audio file required on the second external processing device side.

24. The external processing device is
An identification information issuance processing unit that issues identification information in response to an operation for instructing recording performed by the recording device;
An identification information transmission processing unit for transmitting the identification information to the recording device via the second communication unit and to the second external processing device via the third communication unit; ,
The recording device is
An identification information reception processing unit that receives the identification information transmitted from the information device via the first communication unit;
In the recording device,
The voice storage processing unit adds the identification information to the voice data when generating the first voice file,
The audio file read processing unit reads the first audio file to which the identification information is added from the recording medium,
In the external processing device,
The second audio file transmission processing unit receives the first audio file added with the identification information received by the audio file reception processing unit as the second audio file via the third communication unit. Item 22. The recording system according to Item 21, wherein the recording system is transmitted to the second external processing device.

  According to the recording system described in the supplementary item 24, the identification information issued by the external processing device is transmitted to the recording device and the second external processing device. This identification information is added to the first audio file generated in the recording device. For this reason, the added identification information ensures the correspondence between the first audio file stored in the recording device and the audio file required on the second external processing device side, and the wrong file is stored in the first file. It is possible to suppress transmission to the second external processing device.

  The present invention can be applied to devices capable of recording sound, such as an electronic still camera, a movie camera, a mobile phone with a photographing function, and a recording device.

DESCRIPTION OF SYMBOLS 100 ... Recording system 200 ... Recording apparatus 202 ... Microphone 204 ... Analog front end 206 ... Digital signal processor 208 ... Recording medium 210 ... System control part 212 ... Operation part 216 ... Display part 218 ... Communication part 300 ... PC
302 ... Communication unit 304 ... Auxiliary storage device 306 ... CPU
310 ... Network interface 314 ... Display unit 316 ... Operation input unit 400 ... Server 402 ... Main unit 404 ... CPU
408 ... Output unit 410 ... Input unit 420 ... Network interface 430 ... Auxiliary storage device

Claims (4)

A microphone for voice input,
An audio storage processing unit that processes an audio signal output from the microphone to generate digital audio data, generates a first audio file storing the audio data, and stores the first audio file in a recording medium;
A communication unit capable of communicating with an external processing device;
A voice data transmission processing unit that sequentially transmits the voice data generated by the voice storage processing unit simultaneously with a recording operation to the external processing device via the communication unit;
In executing the recording operation, first communication information transmitted from the external processing device, which is a file name assigned to a second audio file storing the audio data in the external processing device, is transmitted to the communication unit. An identification information reception processing unit for receiving via
When there is a failure in the sequential transmission of the audio data with the external processing device, a transmission failure detection unit that detects the failure in the sequential transmission,
An audio file read processing unit that reads out the first audio file including the audio data that failed in the sequential transmission from the recording medium when the transmission failure detection unit detects the failure in the sequential transmission;
An audio file transmission processing unit that transmits the first audio file read by the audio file reading processing unit to the external processing device via the communication unit;
The voice storage processing unit, when generating the first voice file, for the voice data, the first identification information and that the transmission failure detection unit has detected the failure of the sequential transmission And the second identification information that is the transmission failure information shown, and the first audio file with the first and second identification information added is stored in the recording medium,
The audio file read processing unit reads the first audio file to which the first and second identification information are added from the recording medium. The transmission failure detection unit identifies a data block in which transmission failure has occurred when there is a failure in sequential transmission of the audio data with the external processing device,
The recording apparatus according to claim 1, wherein the transmission failure information includes information indicating a data block in which a transmission failure specified by the transmission failure detection unit has occurred. The audio file read processing unit corresponds to a data block in which a transmission failure is included in the transmission failure information in the first audio file when the transmission failure detection unit detects the failure of the sequential transmission. Read the audio data from the recording medium,
The recording device according to claim 2, wherein the audio file transmission processing unit transmits audio data corresponding to the data block in which the transmission failure has occurred to the external processing device via the communication unit.   The recording apparatus according to claim 1, wherein the communication unit is configured to be communicable in a wireless form.

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