JP2016119561A - Portable device with wireless lan function, and recording system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily improve the sound quality of an audio signal of a moving image taken by a portable device such as a smartphone, without using a computer with a dedicated editing software installed therein.SOLUTION: A smartphone 12 takes a moving image and multiplexes and records a video signal and a first audio signal in a recording medium. On the other hand, a sound recording/reproducing device 10 records a second audio signal of high sound quality. After establishing Wi-Fi connection between the smartphone 12 and the sound recording/reproducing device 10, the sound recording/reproducing device 10 transmits the second audio signal to the smartphone 12, and the smartphone 12 replaces the first audio signal with the second audio signal and multiplexes the video signal and the second audio signal to reconstitute a moving image file.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a portable device, particularly a portable device having a wireless LAN function and a recording system using the portable device.

  Conventionally, various techniques for so-called after-recording (after-recording) have been proposed.

  Patent Document 1 discloses a portable communication device that stores a video file and an audio file separately in a memory, performs a confirmation operation, an after-recording operation, and the like, and then multiplexes and records the video file and the audio file during a storage operation. Have been described.

  Patent Document 2 describes that, for an AV multiplexed file in which a video signal and a first audio signal are multiplexed, the first audio signal is replaced with a second audio signal based on time information.

JP 2003-0788863 A Japanese Patent Laid-Open No. 2003-199045

  By the way, in recent years, smartphones have become more sophisticated, and the movie shooting function has also become more accurate with liquid crystal panels (improves the number of pixels). ing.

  However, the moving image function of smartphones is focused on improving the image quality of images, and the actual situation is that the sound quality of recorded audio signals has not reached a sufficient level. Accordingly, there is an increasing need for users who place particular importance on sound quality to record audio signals with high sound quality using a dedicated recording device and to replace the audio signals of moving images taken with a smartphone.

  An object of the present invention is to provide an apparatus and a recording system that can easily improve the quality of audio signals of moving images taken by a mobile device such as a smartphone without using a computer in which dedicated editing software is installed.

  The present invention comprises a wireless LAN module, a photographing means for photographing a moving image, an input means for inputting a first audio signal at the time of photographing, and a moving image file by multiplexing the video signal and the first audio signal of the moving image. Processing means, and the processing means receives the video signal from the moving image file when receiving a second audio signal recorded by a separate recording device at the time of moving image shooting via the wireless LAN module. The first audio signal is separated, and the video signal and the second audio signal are synchronized based on the correlation between the separated first audio signal and the second audio signal, and the video signal and the second audio signal are established. A video file is reconstructed by multiplexing audio signals.

  In one embodiment of the present invention, the processing means is configured to use the video signal and the second signal based on the correlation between the waveform of the specific frequency component of the separated first audio signal and the specific frequency component of the second audio signal. Establish audio signal synchronization.

  The present invention is also a recording system comprising a portable recording device and a portable device, wherein the portable device inputs a first wireless LAN module, a photographing means for photographing a moving image, and a first audio signal at the time of photographing. And a first processing unit configured to multiplex the video signal and the first audio signal of the moving image to form a moving image file. The portable recording device includes a second wireless LAN module, and the time of shooting. Second input means for inputting the second audio signal and second processing means for recording the second audio signal on a recording medium, wherein the first processing means comprises the first wireless LAN module and the second wireless LAN module. When the second audio signal is received from the portable recording device via a wireless LAN module, the video signal and the first audio signal are transmitted from the moving image file. Audio signal is separated, and synchronization between the video signal and the second audio signal is established based on the correlation between the separated first audio signal and the second audio signal, and the video signal and the second audio signal are It multiplexes and reconfigure | reconstructs a moving image file, It is characterized by the above-mentioned.

  ADVANTAGE OF THE INVENTION According to this invention, the audio signal of the moving image image | photographed with portable apparatuses, such as a smart phone, can be simply made high quality, without using the computer which installed exclusive editing software.

It is a system configuration figure of an embodiment. It is a lineblock diagram of a smart phone of an embodiment. It is a processing flowchart of an embodiment. It is a functional block diagram of the system controller of the embodiment. It is explanatory drawing of the synchronization point of embodiment.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings, taking a smartphone as an example. However, the present invention is applicable to any portable device having a wireless LAN function and a moving image shooting function, and is not necessarily limited to a smartphone.

  FIG. 1 is a system configuration diagram of this embodiment. A portable recording / reproducing apparatus (hereinafter simply referred to as a recording / reproducing apparatus) 10 wirelessly connects to a portable device having a wireless LAN function. In this embodiment, Wi-Fi connection is illustrated as a wireless LAN. Smartphones equipped with Wi-Fi modules are known.

  The recording / reproducing apparatus 10 has a known recording / reproducing function, processes an audio signal input from a built-in microphone or a line input terminal, records it on a recording medium such as an SD card, and the audio signal recorded on the SD card. And output from the built-in speaker. The recording / reproducing apparatus 10 includes a Wi-Fi module and performs Wi-Fi connection with the smartphone 12. The Wi-Fi connection between the recording / reproducing apparatus 10 and the smartphone 12 is basically a one-to-one connection, but may be a one-to-many connection as necessary.

  A user of the recording / playback apparatus 10 inputs an audio signal for playing a desired music part or an audio signal for a band performance at a live performance or the like to the built-in microphone or line input terminal of the recording / playback apparatus 10 for recording. In FIG. 1, a musical instrument 14 such as a guitar is shown, but any other part such as a bass part, vocal part, drum part, or the like may be used. The recording / reproducing apparatus 10 inputs an audio signal, records it on a recording medium such as an SD card, and records it.

  The smartphone 12 includes a Wi-Fi module and is connected to the recording / reproducing apparatus 10 via Wi-Fi. In addition, the smartphone 12 includes a camera module, shoots a still image or a moving image, and records it on a recording medium such as an SD card. Further, the user activates a predetermined application installed on the smartphone 12 and operates the application to control the operation of the recording / reproducing apparatus 10. That is, by operating the application, the smartphone 12 is caused to function as a remote controller for the recording / reproducing apparatus 10, and the recording / reproducing apparatus 10 is instructed to start recording, stop recording, start reproduction, stop reproduction, and the like.

  As shown in FIG. 1, the smartphone 12 captures a moving image such as a band performance where the musical instrument 14 is played, and the video signal and the audio signal (hereinafter, the audio signal acquired when the smartphone 12 captures the moving image is used as the first audio signal). Recorded on the recording medium.

  On the other hand, the recording / reproducing apparatus 10 records the same band performance, and records the audio signal (hereinafter, the audio signal recorded by the recording / reproducing apparatus 10 is referred to as a second audio signal) on a recording medium. The built-in microphone of the recording / playback device 10 has higher functionality than the built-in microphone of the smartphone 12, such as a movable unidirectional stereo condenser microphone that can be used by switching between the AB system and the XY system according to the sound source to be recorded. In addition, the sampling frequency and the number of quantization bits are relatively high, and recording with higher sound quality than the smartphone 12 is possible. Even if a high-performance external microphone is connected to the line input terminal of the recording / reproducing apparatus 10 and an audio signal input from the external microphone is recorded, high-quality sound recording can be performed.

  When the smartphone 12 and the recording / reproducing apparatus 10 are connected via Wi-Fi, the recording / reproducing apparatus 10 transmits the recorded second audio signal to the smartphone 12 via the Wi-Fi connection. The smartphone 12 receives the second audio signal transmitted from the recording / reproducing apparatus 10 and replaces it with the first audio signal acquired at the time of moving image shooting. That is, a predetermined application installed in the smartphone 12 (at least an editing application that can replace an audio signal) requests the recording / playback apparatus 10 to transmit the second audio signal, and the recording / playback apparatus 10 responds to this request. The second audio signal is transmitted to the smartphone 12. The predetermined application of the smartphone 12 separates the video signal and the first audio signal from a moving image file in which the video signal and the first audio signal are multiplexed in a predetermined format (MPEG format, 3GPP format, etc.), and the first audio signal is obtained. The video signal and the second audio signal are multiplexed in a predetermined format by replacing with the second audio signal. At this time, a predetermined application of the smartphone 12 establishes a synchronization point between the video signal and the second audio signal, and multiplexes using the synchronization point to suppress occurrence of a time lag due to replacement.

  FIG. 2 is a configuration block diagram of the smartphone 12. The smartphone 12 includes a Wi-Fi module 20, a camera module 22, a built-in microphone 24, a built-in speaker 30, a display 32, operation buttons 34, a system controller 36, and an SD connector 42.

  The Wi-Fi module 20 is a wireless LAN module, and is a module that performs Wi-Fi connection and data transmission / reception with the recording / reproducing apparatus 10. The Wi-Fi module 20 is activated in response to the operation of the operation button 34 and establishes a Wi-Fi connection with the recording / playback apparatus 10. Further, the Wi-Fi module 20 transmits a command to the recording / reproducing apparatus 10 and supplies the second audio signal received from the recording / reproducing apparatus 10 to the system controller 36 in response to the command. Further, the Wi-Fi module 20 may supply the status information of the recording / reproducing apparatus 10 received from the recording / reproducing apparatus 10 to the system controller 36.

  The camera module 22 captures a still image or a moving image according to a command from the system controller 36 according to the operation of the operation button 34. The camera module 22 outputs a video signal obtained by shooting a still image or a moving image to an interface (I / F) 26.

  The built-in microphone 24 is a monaural or stereo microphone of R channel and L channel, inputs the first audio signal at the time of moving image shooting by the camera module 22, and outputs it to the interface (I / F) 26.

  The interface (I / F) 26 outputs the video signal and the first audio signal to a codec (CODEC) 28.

  A codec (CODEC) 28 converts an input video signal and audio signal into a digital signal, compresses and encodes the signal, and supplies it to the system controller 36. Also, the video signal or audio signal that has been digitized and compression-encoded is decompressed and decoded, the video signal is output to the display 32, and the audio signal is output to the built-in speaker 30. The decompressed / decoded audio signal may be output to an earphone jack (not shown).

  The display 32 is composed of an LCD panel, an organic EL panel, or the like, and displays various types of information of the smartphone 12 and also displays captured still images and moving images.

  The operation button 34 is a button for instructing the operation of the smartphone 12. The operation button 34 includes a physical button and / or a touch icon displayed on the display 32. The operation buttons 34 include a Wi-Fi button for switching Wi-Fi on / off, a button for starting the camera module 22, a button for switching a still image / moving image, and a button for performing post-recording. Here, “after-recording” in the present embodiment, as described above, receives the second audio signal recorded by the recording / playback apparatus 10 and includes the video signal and the first audio signal. It means a process of replacing the first audio signal with the second audio signal and reconstructing a moving image composed of the video signal and the second audio signal.

  The system controller 36 includes a processor and a memory, and controls each unit of the smartphone 12. The system controller 36 executes various processes using the RAM 40 as a working memory according to a processing program recorded in the ROM 38. The various processes include activation / off of the Wi-Fi module 20, establishment of connection with the recording / reproducing apparatus 10, activation and control of the camera module 22, still image or video signal processing, and audio input from the built-in microphone 24. This includes signal processing, recording of video and audio signals to an SD card, playback of video and audio signals, and post-recording processing. The system controller 36 may include a plurality of processors and may cooperate with a PLD (programmable logic device).

  An SD card is attached to the SD connector 42. The system controller 36 records moving image data composed of a video signal and an audio signal on an SD card. Further, a still image file or a moving image file recorded on the SD card is read, a video signal is output to the display 32 via a codec (CODEC) 28, and an audio signal is output to the built-in speaker 30.

  The recording / reproducing apparatus 10 includes a wireless LAN module, a built-in microphone (or line input terminal) for inputting an audio signal, and a controller for processing the audio signal and recording it on a recording medium such as an SD card. In order to distinguish the configuration of each part of the smartphone 12 and the recording / playback apparatus 10, the wireless LAN module, the built-in microphone, and the system controller 36 on the smartphone 12 side are referred to as a first wireless LAN module, a first input unit, and a first processing unit, respectively. The wireless LAN module, built-in microphone (or line input terminal), and controller on the recording / reproducing apparatus 10 side are referred to as a second wireless LAN module, a second input unit, and a second processing unit, respectively.

  FIG. 3 is a flowchart of the after-recording process in the present embodiment. When the camera module 22 of the smartphone 12 is activated to capture a moving image (S101), the video signal and the first audio signal are processed and multiplexed, and recorded on the SD card (S102). For example, when a moving image is recorded according to the MPEG standard, the video signal and the first audio signal are encoded and divided into packets, and the video packet and the audio packet are sequentially switched and time-division multiplexed. Each packet is added with a header, and the header includes identification information for identifying the type of video / audio, and time information. The identification information is defined as stream_id, and the time information is defined as Time Stamp.

  Next, the system controller 36 determines whether or not to perform the post-recording process (S103). When the user operates the operation button 34 to instruct post-recording processing (YES in S103), the system controller 36 receives the recording file of the second audio signal from the recording / playback apparatus 10 via the Wi-Fi connection (S104).

  Next, the system controller 36 reads the moving image file designated by the operation button 34 from the SD card (S105), and separates the video signal and the first audio signal constituting the read moving image file (S106). Since the header of each packet includes information stream_id for identifying the type of video / audio, this information is used to separate the video signal and the first audio signal.

Next, the system controller 36 sets a synchronization point as a time reference for multiplexing the video signal and the second audio signal (S107), and the first audio signal is converted to the second audio signal based on the set synchronization point. And is multiplexed with the video signal (S108). Therefore,
Video file before dubbing = video signal + first audio signal,
After-recording video file = video signal + second audio signal. In connection with this, you may change the name of a moving image file before and after dubbing. For example, when the moving image file before dubbing is “141120_0000.mp4”, the moving image file after dubbing is “141120_0000-1.mp4”. The synchronization point is time information for synchronizing the video signal and the second audio signal, but in this embodiment, the video signal and the second audio signal are not directly compared, but the first audio signal and the second audio signal are not compared. The signals are compared and detected based on the similarity between the two signals. The similarity can be calculated by convolution calculation of both signals.

  After reconstructing the moving image file using the second audio signal, the system controller 36 records the after-recording moving image file on the SD card (S109).

  Hereinafter, the after-recording process in the system controller 36 will be described in more detail.

  FIG. 4 is a functional block diagram of the system controller 36. The system controller 36 includes a separation unit 361, a comparison unit 362, a synchronization point detection unit 363, and a multiplexing unit 364 as functional blocks.

  The separation unit 361 receives the video signal and the first audio signal constituting the moving image file, and separates the video signal and the first audio signal using identification information included in the header of each packet. The video signal is supplied as it is to the multiplexing unit 364, and the first audio signal is supplied to the comparison unit 362.

  The comparison unit 362 receives the first audio signal from the separation unit 361 and the second audio signal received from the recording / playback apparatus 10 via the Wi-Fi connection, and compares the two. That is, the comparison unit 362 decompresses and decodes the compression-coded first audio signal to generate the original audio signal, and similarly decompresses and decodes the second audio signal to generate the original audio signal. Since the second audio signal is recorded by the recording / reproducing apparatus 10, it is not always the same as the format of the first audio signal. Therefore, the system controller 36 receives the format information of the second audio signal from the recording / reproducing apparatus 10 and generates the second audio signal waveform based on the format information. Then, the comparison unit 362 compares the first audio signal and the second audio signal. Specifically, the degree of similarity between both signals is calculated by calculating convolution of both signals or calculating a cross-correlation function. Since the two signals are both discrete values, the convolution operation is not convolution integration but convolution sum. When the sampling frequency of the first audio signal and the sampling frequency of the second audio signal are different, the number of samples of the second audio signal may be thinned out so that the number of samples of both signals is the same (usually, recording and reproduction) The sampling frequency of the device 10 is higher than that of the smartphone 12).

  Using the similarity (or correlation) calculated by the comparison unit 362, the synchronization point detection unit 363 detects a time timing at which the similarity is the highest as a synchronization point. This synchronization point is a synchronization point between the first audio signal and the second audio signal, but since the video signal and the first audio signal are originally synchronized, the synchronization point between the first audio signal and the second audio signal is It functions as a synchronization point between the video signal and the second audio signal as it is. That is, the comparison unit 362 and the synchronization point detection unit 363 do not compare the video signal and the second audio signal, but synchronize with the video signal in order to establish synchronization between the video signal and the second audio signal. It can be said that one audio signal is used and synchronization between the video signal and the second audio signal is established via the first audio signal. The synchronization point detection unit 363 supplies the detected synchronization point to the multiplexing unit 364.

  FIG. 5 is a schematic diagram of the waveform 100 of the first audio signal and the waveform 200 of the second audio signal. Since the first audio signal and the second audio signal are both generated from the same sound source, they have a certain correlation or similarity. However, due to the difference in performance between the built-in microphone of the smartphone 12 and the built-in microphone of the recording / playback apparatus 10, there is a difference between both waveforms. Assuming that the point at which the two signal waveforms are most coincident is the time t1 in the first audio signal and the time t2 in the second audio signal, this (t1, t2) is detected as a synchronization point.

  The multiplexing unit 364 multiplexes the video signal (compressed and encoded video signal) and the second audio signal (compressed and encoded second audio signal) supplied from the separating unit 361. At this time, multiplexing is performed based on the synchronization point detected by the synchronization point detection unit 363. Specifically, time information is added to the header of the packet of the second audio signal with reference to the synchronization point, and is time-division multiplexed with the packet of the video signal. For example, if the packet of the second audio signal is the second audio packet 1, the second audio packet 2, the third audio packet 3,..., And the packet corresponding to the synchronization point is the second audio packet 2, The same time information as the time information added to the first packet of the video signal is added to the header of the audio packet 2, and the video signal and the header of the subsequent second audio signal packet are referred to based on this time information. Similarly, time information is set and multiplexed. In the MPEG standard, the time information Time Stamp includes a DTS indicating the decoding start time and a PTS indicating the display / sound generation time, both of which are set based on the synchronization point.

  In this way, in order to synchronize the time information included in the header of the packet of the second audio signal with the time information included in the packet of the video signal, the video signal and the second audio signal can be reproduced even when the post-recording moving image file is reproduced. Therefore, it is possible to enjoy high-quality audio recorded by the recording / reproducing apparatus 10.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to this, A various deformation | transformation is possible.

  For example, in the present embodiment, in order to establish synchronization between the video signal and the second audio signal, the video signal and the second audio signal are calculated from the similarity between the first audio signal and the second audio signal, focusing on the first audio signal. However, instead of changing the correlation between the waveforms of the first audio signal and the second audio signal, attention is paid to a specific frequency component, for example, a vocal signal component, included in the first audio signal and the second audio signal. The synchronization between the video signal and the second audio signal may be established from the similarity of the signal components of these vocals.

  In the present embodiment, the similarity between the first audio signal and the second audio signal is calculated by convolution, but this is only an example, and a known calculation for calculating the similarity or correlation between two signals. It is possible to use a technique. In the present embodiment, both the first audio signal and the second audio signal are treated as discrete values and the similarity is calculated, but the original analog signal waveforms of the first audio signal and the second audio signal are compared with each other. Also good.

  Further, the time information may be transmitted from the smartphone 12 to the recording / reproducing apparatus 10 via the Wi-Fi connection, and the recording / reproducing apparatus 10 may record the second audio signal using the time information received from the smartphone 12. In this case, since the video signal and the second audio signal have common time information, the system controller 36 can multiplex the video signal and the second audio signal using this time information. However, when the recording / reproducing apparatus 10 receives a command from the smartphone 12 and starts recording, there is a possibility that a time lag occurs between the moving image shooting timing by the smartphone 12 and the recording timing by the recording / reproducing apparatus 10. In this case, when the recording / playback apparatus 10 is in a recording mode (recording standby state) in cooperation with the smartphone 12, it is set to perform pre-recording of an audio signal for a predetermined time using the buffer memory. In response to the command received from, an audio signal that coincides with the moving image shooting timing may be read from the buffer memory to start recording.

  In the present embodiment, as a mode for establishing synchronization between the video signal and the second audio signal, a mode using the similarity between the first audio signal and the second audio signal, and a specific frequency component (for example, vocal component) of both signals. You may comprise so that a user can select suitably the mode which uses a similarity degree, and the mode which uses the time information transmitted from the smart phone 12 by operation of the operation button 34. FIG.

  Further, in the present embodiment, a plurality of recording / playback apparatuses 10 record different music parts of the same band performance, transmit them to the smartphone 12, and mix down with the smartphone 12 to generate a final second audio signal. This may be multiplexed with the video signal. Also in this case, the synchronization point may be detected by comparing the second audio signal transmitted from each recording / reproducing apparatus 10 with the first audio signal included in the moving image file.

  In the present embodiment, Wi-Fi connection is exemplified as the wireless connection, but Bluetooth or the like may be used.

  In the present embodiment, it is assumed that the second audio signal recorded by the recording / playback apparatus 10 is relatively higher in sound quality than the first audio signal recorded by the smartphone 12. The application may selectively reproduce the first audio signal and the second audio signal so that the user can hear and compare with each other, and the after-recording process may be executed when the user selects the second audio signal. In addition, the waveform 100 of the first audio signal and the waveform 200 of the second audio signal shown in FIG. 5 are displayed in parallel corresponding to the time axis so that the time axis (synchronization point) of the selected waveform can be finely adjusted manually. Also good. This is a necessary function for users who are not satisfied with the result of the automatic execution process or who want to deliberately shift the synchronization point (to create a moving image such as satellite relay).

  DESCRIPTION OF SYMBOLS 10 Recording / reproducing apparatus, 12 Smartphone, 14 Musical instrument, 20 Wi-Fi module, 22 Camera module, 24 Built-in microphone, 30 Built-in speaker, 32 Display, 34 Operation button, 36 System controller, 42 SD connector.

Claims (3)

A wireless LAN module;
Shooting means for shooting videos,
Input means for inputting the first audio signal at the time of shooting;
Processing means for multiplexing the video signal of the moving image and the first audio signal to form a moving image file;
With
The processing means separates the video signal and the first audio signal from the moving image file when receiving the second audio signal recorded by a separate recording device at the time of moving image shooting via the wireless LAN module. And establishing synchronization between the video signal and the second audio signal based on the similarity between the separated first audio signal and the second audio signal, and multiplexing the video signal and the second audio signal. A portable device having a wireless LAN function characterized by reconstructing a video file. In the portable apparatus provided with the wireless LAN function according to claim 1,
The processing means establishes synchronization between the video signal and the second audio signal based on a similarity between the separated specific frequency component of the first audio signal and the specific frequency component of the second audio signal. A portable device having a wireless LAN function. A recording system comprising a portable recording device and a portable device,
The portable device is
A first wireless LAN module;
Shooting means for shooting videos,
First input means for inputting a first audio signal at the time of shooting;
First processing means for multiplexing a video signal and a first audio signal of the moving image to form a moving image file;
With
The portable recording device is:
A second wireless LAN module;
Second input means for inputting a second audio signal at the time of shooting;
Second processing means for recording the second audio signal on a recording medium;
With
When the second processing unit receives the second audio signal from the portable recording device via the first wireless LAN module and the second wireless LAN module, the first processing unit receives the video signal and the first signal from the moving image file. An audio signal is separated, and synchronization between the video signal and the second audio signal is established based on a similarity between the separated first audio signal and the second audio signal, and the video signal and the second audio signal are established. A recording system that multiplexes and reconstructs a video file.

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