JP2012185343A - Photographing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a photographing device capable of executing various kinds of operations in synchronization with a specific voice.SOLUTION: The photographing device includes voice input means 140 to which an external voice is inputted from the outside, voice analysis means 171 analyzing the external voice and extracting an external voice characteristic being the characteristic of the external voice, first voice characteristic storage means 172 storing the characteristic of a first specific voice as a first specific voice characteristic, and first determination means 173 comparing the external voice characteristic with the first specific voice characteristic and determining whether or not a photographing preparation operation is started based on the comparison result.

Description

  The present invention relates to a photographing apparatus.

  2. Description of the Related Art Conventionally, a photographing apparatus including a sound collecting microphone is known for collecting sound during moving image shooting when shooting a moving image (see, for example, Patent Document 1).

JP 2007-104316 A

  On the other hand, in certain shooting scenes such as car races, there are scenes where it is desirable to start shooting preparation operations or to shoot subject images in synchronization with specific sounds such as car driving sounds. In the conventional imaging device, it is not possible to perform an operation synchronized with a specific sound in this way.

  The problem to be solved by the present invention is to provide a photographing apparatus capable of executing various operations in synchronization with a specific sound.

  The present invention solves the above problems by the following means. In the following description, the reference numerals corresponding to the drawings showing the embodiments of the present invention are used for explanation, but these reference numerals are only for facilitating the understanding of the present invention and are not intended to limit the invention. Absent.

  [1] The photographing apparatus of the present invention includes an audio input means (140) for inputting external sound from the outside, and an audio analysis means for analyzing the external sound and extracting external sound characteristics that are characteristics of the external sound. (171), the first sound characteristic storage means (172) for storing the characteristic of the first specific sound as the first specific sound characteristic, the external sound characteristic and the first specific sound characteristic are compared, First determination means (173) for determining whether or not to start the photographing preparation operation based on the comparison result is provided.

  [2] In the photographing apparatus of the present invention, the external sound characteristic and the first specific sound characteristic include sound volume information and sound waveform information, and the first determination means (173) is configured to store the sound volume of the external sound. And the difference between the sound volume of the first specific sound and the sound waveform of the external sound and the sound waveform of the first specific sound, and each of the differences is determined by a predetermined threshold value. In the following cases, it can be configured to activate the shooting preparation operation.

  [3] In the photographing apparatus of the present invention, the external sound characteristic and the first specific sound characteristic include sound volume information and fundamental frequency information, and the first determination means (173) includes a sound volume of the external sound. And the difference between the volume of the first specific sound and the basic frequency of the external sound and the basic frequency of the first specific sound, and each of the differences is a predetermined threshold value determined in advance. In the following cases, it can be configured to activate the shooting preparation operation.

  [4] In the photographing apparatus of the present invention, the sound analysis means (171) repeatedly extracts the external sound characteristics at a predetermined timing, and the first determination means (173) repeats at a predetermined timing, The external audio characteristic and the first audio characteristic can be compared.

  [5] In the photographing apparatus of the present invention, when the user half-presses the release button, the sound analysis means (171) extracts the external sound characteristics of the external sound input to the sound input means when half-pressed. The first sound characteristic storage means (172) can be configured to store the external sound characteristic as the first specific sound characteristic.

  [6] In the photographing apparatus of the present invention, second sound characteristic storage means (174) for storing a characteristic of the second specific sound different from the first specific sound as a second specific sound characteristic; A second determination means (175) for comparing the external audio characteristic and the second specific audio characteristic and determining whether or not to perform shooting based on the comparison result when the operation is in operation; , Can be further provided.

  [7] In the photographing apparatus of the present invention, the external audio characteristic and the second specific audio characteristic include volume information and audio waveform information, and the second determination means (175) is configured to output the volume of the external sound. And the difference between the volume of the second specific sound and the sound waveform of the external sound and the sound waveform of the second specific sound, and each difference is determined by a predetermined threshold value. It can be configured to perform shooting when:

  [8] In the photographing apparatus of the present invention, the external sound characteristic and the second specific sound characteristic include volume information and fundamental frequency information, and the second determination means (175) includes a volume of the external sound. And the difference between the volume of the second specific sound and the difference between the fundamental frequency of the external sound and the fundamental frequency of the second specific sound, and each difference is a predetermined threshold value determined in advance. It can be configured to perform shooting when:

  [9] In the photographing apparatus of the present invention, the sound analysis means (171) repeatedly extracts the external sound characteristics at a predetermined timing, and the second determination means (175) repeats at a predetermined timing, The external audio characteristic and the second audio characteristic can be compared.

  [10] In the photographing apparatus of the present invention, when the user half-presses the release button, the sound analysis means (171) extracts the external sound characteristics of the external sound input to the sound input means when half-pressed. The second sound characteristic storage means (174) may be configured to store the external sound characteristic as the second specific sound characteristic.

  [11] In the photographing apparatus of the present invention, when the user fully presses the release button, the voice analysis means (171) receives the external sound input to the voice input means from the time when the release button is fully pressed to a predetermined time before. An external audio characteristic can be extracted, and the second audio characteristic storage means (174) can be configured to store the external audio characteristic as the second specific audio characteristic.

  [12] In the photographing apparatus of the present invention, a recording unit that records external audio input from the audio input unit by a user operation, and an external audio recorded in the external audio recording unit by a user operation And setting means (150) for setting the voice to be stored as the first specific voice characteristic in the first voice characteristic storage means and / or the voice to be stored as the second specific voice characteristic in the second voice characteristic storage means. It can be constituted as follows.

  ADVANTAGE OF THE INVENTION According to this invention, the imaging device which can perform various operation | movement synchronizing with a specific audio | voice can be provided.

FIG. 1 is a main part configuration diagram showing a single-lens reflex digital camera according to an embodiment of the present invention. FIG. 2 is a block diagram illustrating a configuration of the camera control unit 170. FIG. 3 is a diagram showing the volume information of the piano sound as a specific example of the external sound collected by the sound collecting microphone. FIG. 4 is a diagram showing information on the sound waveform of a piano sound as a specific example of the external sound collected by the sound collecting microphone. FIG. 5 is a diagram showing amplitude data for each frequency obtained by Fourier transforming the speech waveform shown in FIG. FIG. 6 is a diagram showing phase data for each frequency obtained by Fourier transforming the speech waveform shown in FIG. FIG. 7 is a diagram for explaining an example of a method for calculating the volume difference ΔV between the external sound and the start-up sound. FIG. 8 is a diagram for explaining an example of a method for calculating the voice waveform difference ΔW between the external voice and the startup voice. FIG. 9 is a flowchart showing the operation of the camera 1 when the “sound memory photographing mode” is selected. FIG. 10 is a flowchart showing the operation of the camera 1 when the “sound detection automatic shooting mode” is selected. FIG. 11 is a diagram illustrating an example of a scene to which the present embodiment is applied. FIG. 12 is a diagram for explaining an external audio analysis method according to another embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a configuration of a digital camera 1 according to the present embodiment, and a part of the illustration and description of a general configuration of the camera other than the configuration related to the imaging apparatus of the present invention are omitted.

  The camera 1 of the present embodiment includes a camera body 100 and a lens barrel 200, and the camera body 100 and the lens barrel 200 are detachably coupled by a mount unit 300. In the camera 1 of the present embodiment, the lens barrel 200 is replaceable depending on the purpose of shooting.

  The lens barrel 200 includes a photographing optical system including a photographing lens 210 and a diaphragm device 220.

  The photographing lens 210 includes a lens group including a plurality of lenses, and includes a focus lens for performing focus adjustment, a zoom lens for adjusting photographing magnification, and the like. Based on the drive signal from 230, the drive motor for driving each lens is driven to move in the direction of the optical axis L1. The movement of each lens is also performed by rotating a focus ring and a zoom ring provided in the lens barrel 200.

  The aperture device 220 is configured such that the aperture diameter around the optical axis L1 can be adjusted in order to limit the amount of light beam that passes through the photographing optical system and reaches the image sensor 110. Adjustment of the aperture diameter by the aperture device 220 is performed, for example, by transmitting a signal corresponding to the aperture value calculated in the automatic exposure mode from the camera control unit 170 to the aperture drive unit via the lens control unit 230. . The aperture diameter is adjusted by a manual operation by the operation unit 150 provided in the camera body 100, and a signal corresponding to the set aperture value is transmitted from the camera control unit 170 to the aperture drive unit via the lens control unit 230. It is also done by doing.

  The lens barrel 200 is provided with a lens control unit 230. The lens control unit 230 includes a microprocessor and peripheral components such as a memory, and is electrically connected to the camera control unit 170, and receives information such as a photographing magnification, a defocus amount, and an aperture control signal from the camera control unit 170. At the same time, lens information such as the lens position and aperture value of each lens constituting the taking lens 210 is transmitted to the camera control unit 170.

  On the other hand, the camera body 100 includes a mirror system 120 for guiding the light flux from the subject to the image sensor 110, the finder 135, the photometric sensor 137, and the focus detection module 160. The mirror system 120 includes a quick return mirror 121 that rotates by a predetermined angle between the observation position and the photographing position of the subject around the rotation axis 123, and the quick return mirror 121 that is pivotally supported by the quick return mirror 121. And a sub mirror 122 that rotates in accordance with the rotation.

  In FIG. 1, a state where the mirror system 120 is at the observation position of the subject is indicated by a solid line, and a state where the mirror system 120 is at the photographing position of the subject is indicated by a two-dot chain line. The mirror system 120 is inserted on the optical path of the optical axis L1 in the state where the subject is in the observation position, while rotating so as to retract from the optical path of the optical axis L1 in the state where the subject is in the photographing position.

  The quick return mirror 121 is composed of a half mirror, and in a state where the subject is at the observation position, the quick return mirror 121 reflects a part of the light flux (optical axes L2 and L3) from the subject (optical axis L1). Then, the light is guided to the finder 135 and the photometric sensor 137, and a part of the light beam (optical axis L4) is transmitted and guided to the sub mirror 122. On the other hand, the sub mirror 122 is configured by a total reflection mirror, and guides the light beam (optical axis L4) transmitted through the quick return mirror 121 to the focus detection module 160.

  Therefore, when the mirror system 120 is at the observation position, the luminous flux (optical axis L1) from the subject is guided to the finder 135, the photometric sensor 135, and the focus detection module 160, and the subject is observed and exposed. Calculation and detection of the focus adjustment state of the photographic lens 210 are executed. When the photographer fully presses the release button, the mirror system 120 rotates to the photographing position, the light flux from the subject (optical axis L1) is guided to the image sensor 110, and the photographed image data is stored in the memory 180.

  The image sensor 110 is provided on the camera body 100 on the optical axis L1 of the light beam from the subject and at a position that is a planned focal plane of the photographing lens 210. The imaging element 110 is a two-dimensional array of a plurality of photoelectric conversion elements, and can be configured by a two-dimensional CCD image sensor, a MOS sensor, a CID, or the like. The electrical image signal photoelectrically converted by the image sensor 110 is subjected to image processing by the camera control unit 170 and then stored in the memory 180. Note that the memory 180 for storing the photographed image can be configured by a built-in memory or a card-type memory.

  On the other hand, the light beam from the subject light reflected by the quick return mirror 121 forms an image on a focusing screen 131 disposed on a surface optically equivalent to the image sensor 110, and passes through the pentaprism 133 and the eyepiece lens 134. It can be observed by the photographer. At this time, the transmissive liquid crystal display 132 superimposes and displays a focus detection area mark on the subject image on the focusing screen 131 and relates to shooting such as the shutter speed, aperture value, and number of shots in an area outside the subject image. Display information. As a result, the photographer can observe the subject, its background, and photographing related information through the finder 135 in the photographing preparation state.

  The photometric sensor 137 is composed of a two-dimensional color CCD image sensor or the like, and divides the photographing screen into a plurality of regions and outputs a photometric signal corresponding to the luminance of each region in order to calculate an exposure value at the time of photographing. Image information detected by the photometric sensor 137 is output to the camera control unit 170 and used for automatic exposure control.

  The focus detection module 160 is fixed at a position on the optical axis L4 of the light beam reflected by the sub mirror 122 and optically equivalent to the imaging surface of the image sensor 110, and detects the phase difference using subject light. The defocus amount of the photographing optical system is calculated according to the method, the lens drive amount is calculated based on the defocus amount, and this is transmitted to the lens controller 170. Then, the lens driving amount is transmitted from the lens control unit 170 to the lens control unit 230, whereby the position of the focus lens included in the photographing lens 210 is adjusted.

  The operation unit 150 is a shutter release button or an input switch for the photographer to set various operation modes of the camera 1 and selects a “sound storage photographing mode” for storing a start-up sound and an imaging sound described later. And a switch for selecting the “sound detection automatic shooting mode” for automatically starting shooting and shooting of the camera 1 based on the sound input from the sound collection microphone 140. It has. Various modes and operation signals set by the operation unit 150 are transmitted to the camera control unit 170. The shutter release button switch includes a first switch SW1 that is turned on when the button is half-pressed and a second switch SW2 that is turned on when the button is fully pressed.

  The display unit 190 acquires image information from the image sensor 110 via the camera control unit 170, and displays an image based on the acquired image information on a display provided in the display unit 190.

  The camera body 100 is provided with a sound collecting microphone 140. The sound collecting microphone 140 collects sound around the camera 1 and transmits the collected sound signal to the camera control unit 170.

  The camera body 100 is provided with a camera control unit 170. The camera control unit 170 includes peripheral components such as a microprocessor and a memory, and is electrically connected to the lens control unit 230 through an electrical signal contact unit provided in the mount unit 300, and receives lens information from the lens control unit 230. In addition, various control signals are transmitted to the lens control unit 230. The camera control unit 170 reads out image information from the image sensor 110 as described above, performs predetermined information processing as necessary, and outputs the information to the memory 180 and the display unit 190. Furthermore, the camera control unit 170 controls the entire camera 1 such as correction of captured image information and detection of the focus adjustment state and the aperture adjustment state of the lens barrel 200.

  FIG. 2 is a block diagram showing the configuration of the camera control unit 170. As shown in FIG. As shown in FIG. 2, the camera control unit 170 includes an audio analysis unit 171, an activation audio storage unit 172, a first audio characteristic comparison unit 173, an imaging audio storage unit 174, a second audio characteristic comparison unit 175, and An activation control unit 176 is included.

  The sound analysis unit 171 acquires a sound signal of external sound around the camera 1 collected by the sound collection microphone 140 and analyzes the acquired sound signal. Specifically, the voice analysis unit 171 analyzes the voice signal input from the sound collection microphone 140 to thereby obtain the voice characteristics of the external voice, that is, volume information, voice waveform information, and fundamental frequency information. To extract. 3 and 4, as specific examples of the external sound collected by the sound collecting microphone 140, the volume information of the piano sound (piano sound when a specific key is pressed) and the sound waveform information are shown. An example is shown. Here, FIG. 3 is a diagram showing information on the volume of the piano sound. In FIG. 3, the change in the volume with respect to time is shown as a graph. In FIG. 3, the volume is standardized with the maximum volume being 1. FIG. 4 is a diagram showing information on the sound waveform of the piano sound. In FIG. 4, the change of the sound waveform with respect to time is shown as a graph. In FIG. 4, the amplitude of the speech waveform is normalized and represented with a maximum amplitude of 1.

  Then, the sound analysis unit 171 analyzes the sound signal input from the sound collection microphone 140, extracts the volume information of the external sound and the sound waveform information, as shown in FIGS. Performs a process of decomposing the audio signal for each frequency by Fourier transforming the audio waveform based on the information of the audio waveform. 5 shows the amplitude data for each frequency obtained by Fourier transforming the speech waveform shown in FIG. 4, and FIG. 6 shows the frequency obtained by Fourier transforming the speech waveform shown in FIG. The phase data for each is shown respectively. In FIG. 5, the amplitude is normalized and represented with the maximum amplitude being 1. Then, the voice analysis unit 171 extracts basic frequency information from the amplitude data for each frequency obtained by Fourier transforming the voice waveform. Here, the fundamental frequency is the frequency of the lowest frequency component among the frequency components constituting the speech waveform. In the examples shown in FIGS. 5 and 6, the fundamental frequency exists in the vicinity of 1000 Hz.

  Thus, the volume information, the sound waveform information, and the fundamental frequency information of the external sound extracted by the sound analysis unit 171 are output to the activation sound storage unit 172 and the large sound characteristic comparison unit 173.

  The start-up sound storage unit 172 stores the sound characteristics information of the start-up sound to be used for starting up the shooting preparation operation of the camera 1, that is, the start-up sound volume information, sound waveform information, and fundamental frequency information. Remember. In the present embodiment, for example, in the “sound storage shooting mode”, when the shutter release button is half-pressed (first switch SW1 is turned on), the sound input from the sound collection microphone 140 is used as the start-up sound storage unit 172. It can be set as the start-up voice for memorizing it. That is, in this embodiment, in the “sound recording mode”, when the shutter release button is half-pressed, the voice input from the sound collection microphone 140 is used as the startup voice, and the voice characteristic information of the voice is started up. It can be stored in the voice storage unit 172 for use. As a specific example, for example, a voice having the voice characteristics shown in FIGS. 3 to 6 is a voice inputted from the sound collecting microphone 140 when the shutter release button is half-pressed (first switch SW1 is turned on). In some cases, the sound characteristics of the sound can be stored in the activation sound storage unit 172.

  The first sound characteristic comparison unit 173 receives the sound characteristic of the external sound input from the sound collecting microphone 140 (hereinafter referred to as “external sound characteristic” as appropriate) from the sound analysis unit 171, and the external sound characteristic and The voice characteristics of the startup voice stored in the startup voice storage unit 172 are compared, and the voice characteristics of the external voice and the voice characteristics of the startup voice stored in the startup voice storage unit 172 are found. It is determined whether or not they match. That is, the first sound characteristic comparison unit 173 determines whether or not the external sound matches the activation sound stored in the activation sound storage unit 172.

  Judgment as to whether or not the external sound input from the sound collection microphone 140 and the start-up sound stored in the start-up sound storage unit 172 match is performed as follows. That is, first, the first voice characteristic comparison unit 173 calculates the volume difference ΔV and the voice waveform difference ΔW based on the volume and voice waveform of the external voice and the volume and voice waveform of the activation voice. Here, FIG. 7 shows an example of a method for calculating the volume difference ΔV between the external sound and the start-up sound, and FIG. 8 shows an example of a method for calculating the sound waveform difference ΔW between the external sound and the start-up sound. Are shown respectively. As shown in FIG. 7, the first audio characteristic comparison unit 173 calculates the difference between the volume of the external audio and the volume of the activation audio for each time, and integrates the calculated difference over time, thereby obtaining a volume difference. ΔV is calculated. Further, as shown in FIG. 8, the first voice characteristic comparison unit 173 calculates the difference between the voice waveform of the external voice and the voice waveform of the activation voice for each time, and integrates the calculated difference over time. Thus, the voice waveform difference ΔW is calculated by time-integrating the calculated difference.

Then, the first sound characteristic comparison unit 173 determines whether or not the external sound matches the start sound based on the calculated volume difference ΔV and sound waveform difference ΔW. Specifically, when the calculated volume difference ΔV is equal to or less than a predetermined first sound volume threshold value V ₁ and the calculated sound waveform difference ΔW is equal to or less than a predetermined first sound waveform threshold value W ₁ , , It is determined that the start-up voice matches. Note that the first sound volume threshold value V ₁ can be set to a value that allows the external sound and the activation sound to be determined to have substantially the same sound volume. Similarly, the first sound waveform threshold value W ₁ can be set to a value that allows the external sound and the activation sound to be determined to have substantially the same sound volume waveform.

  When the first sound characteristic comparison unit 173 determines that the external sound and the start-up sound stored in the start-up sound storage unit 172 match, the first sound characteristic comparison unit 173 starts the shooting preparation operation of the camera 1. Is sent to the activation control unit 176 to cause the activation control unit 176 to execute processing for starting up the photographing preparation operation of the camera 1.

  When a plurality of activation voices are stored in the activation voice storage unit 172, the first voice characteristic comparison unit 173 has at least one activation voice having a voice characteristic that matches the voice characteristic of the external voice. If it exists, it can be determined that the external voice and the startup voice stored in the startup voice storage unit 172 match.

  In addition, the imaging audio storage unit 174 stores audio characteristic information of imaging audio to be used for imaging by the camera 1, that is, volume information of startup audio, audio waveform information, and fundamental frequency information. To do. In the present embodiment, for example, in the “sound detection automatic shooting mode”, the sound input from the sound collection microphone 140 when the shutter release button is fully pressed (the second switch SW2 is turned on) The audio for imaging to be stored in the unit 174 can be obtained. That is, in the present embodiment, in the “sound detection automatic shooting mode”, when the shutter release button is fully pressed, the sound input from the sound collection microphone 140 is used as imaging sound, and the sound characteristic information of the sound is displayed. The imaging voice storage unit 174 can store the image. As a specific example, for example, a voice having the voice characteristics shown in FIGS. 3 to 6 is a voice inputted from the sound collection microphone 140 when the shutter release button is fully pressed (second switch SW2 is turned on). In some cases, the audio characteristics of the audio can be stored in the imaging audio storage unit 174.

  The second sound characteristic comparison unit 175 receives the sound characteristic of the external sound input from the sound collection microphone 140 from the sound analysis unit 171 when the shooting preparation operation of the camera 1 is activated by the activation control unit 176. The external audio characteristics are compared with the audio characteristics of the imaging audio stored in the imaging audio storage unit 174, and the audio characteristics of the external audio and the imaging audio storage unit 174 stored in the imaging audio storage unit 174 are compared. Judgment is made as to whether or not the voice characteristics of the elephant voice match. That is, the second sound characteristic comparison unit 175 determines whether or not the external sound matches the imaging sound stored in the imaging sound storage unit 174.

It should be noted that whether or not the external sound input from the sound collection microphone 140 and the imaging sound stored in the imaging sound storage unit 174 match is determined by the first sound characteristic comparison unit described above. It can be performed in the same manner as 173. That is, the second sound characteristic comparison unit 175 calculates the sound volume difference ΔV and the sound waveform difference ΔW based on the sound volume and sound waveform of the external sound and the sound volume and sound waveform of the imaging sound, and the sound volume difference ΔV is the second sound volume difference ΔV. When the sound volume difference V is equal to or smaller than the sound volume threshold V ₂ and the sound waveform difference ΔW is equal to or smaller than the second sound waveform threshold W ₂ , it can be determined that the external sound and the imaging sound match. The second sound volume threshold value V ₂ and the second sound waveform threshold value W ₂ can be set in the same manner as the first sound volume threshold value V ₁ and the first sound waveform threshold value W ₁ described above. The 2 sound volume threshold value V ₂ and the second sound waveform threshold value W ₂ may be the same as the first sound volume threshold value V ₁ and the first sound waveform threshold value W ₁ described above, respectively.

  When the second audio characteristic comparison unit 175 determines that the external audio and the imaging audio stored in the imaging audio storage unit 174 match, the second audio characteristic comparison unit 175 causes the camera 1 to perform imaging. Are sent to the activation control unit 176 to cause the activation control unit 176 to execute processing for causing the camera 1 to perform imaging.

  When a plurality of imaging sounds are stored in the imaging sound storage unit 174, the second sound characteristic comparison unit 175 has at least one activation sound having a sound characteristic that matches the sound characteristic of the external sound. If it exists, it can be determined that the external audio and the imaging audio stored in the imaging audio storage unit 174 match.

  The activation control unit 176 controls activation of the shooting preparation operation of the camera 1 and activation of the imaging operation of the camera 1. Specifically, the activation control unit 176 stores the external audio and the activation audio storage unit 172 by the first audio characteristic comparison unit 173 described above when the “sound detection automatic shooting mode” is selected. When it is determined that the startup voice matches the startup voice, the startup signal for starting the shooting preparation operation of the camera 1 is received from the first voice characteristic comparison unit 173, and the received startup voice is received. Based on the signal, the photographing preparation operation of the camera 1 is started. That is, when the activation control unit 176 receives the activation signal from the first sound characteristic comparison unit 173, the activation control unit 176 activates the image sensor 110, the photometric sensor 137, the focus detection module 160, and the display unit 190. Thus, the activation control unit 176 acquires the imaging signal by the imaging device 110, the photometric signal by the photometric sensor 137, the acquisition of the focus detection signal by the focus detection module 160, the captured image by the display unit 190, and the like. Each operation of the display is started.

  In addition, when the “sound detection automatic photographing mode” is selected, the activation control unit 176 performs the above-described second sound characteristic comparison unit 175 in the state where the photographing preparation operation of the camera 1 is activated. When it is determined that the external audio and the imaging audio stored in the imaging audio storage unit 174 match, the second audio characteristic comparison unit 175 causes the camera 1 to perform imaging. The signal is received, and the image sensor 110 is caused to capture a subject image based on the received imaging signal.

  Furthermore, when a mode other than the “sound detection automatic shooting mode” is selected, the activation control unit 176 performs the shooting operation of the camera 1 when an imaging operation is performed by the photographer via the operation unit 150. The activation of the shooting preparation operation and the activation of the imaging operation of the camera 1 are controlled. That is, when the shutter release button is half-pressed (first switch SW1 is turned on), the activation control unit 176 activates the shooting preparation operation of the camera 1, and further, the shooting preparation operation of the camera 1 is activated. In this case, when the shutter release button is fully pressed (second switch SW2 is turned on), the imaging operation of the camera 1 is started.

  Next, an operation example of the camera according to the present embodiment will be described.

  Hereinafter, an operation example in the case where the “sound memory photographing mode” for storing the start-up sound and the image pickup sound is selected will be described. Here, FIG. 9 is a flowchart showing the operation of the camera 1 when the “sound memory photographing mode” is selected.

  The operation described below is started when the power of the camera 1 is turned on and the “sound recording mode” is selected. The camera 1 of the present embodiment is set to a low power consumption mode (a mode in which the image sensor 110, the photometric sensor 137, the focus detection module 160, and the display unit 190 are turned off) when the power is turned on. Is done.

  First, in step S101, it is determined whether or not the photographer has pressed the shutter release button halfway (first switch SW1 is turned on). If the first switch SW1 is turned on, the process proceeds to step S102, and the first switch SW1 is turned on. If it is not on, it waits in step S101.

  In step S102, the activation control unit 176 performs a process for starting the shooting preparation operation of the camera 1. Specifically, the activation control unit 176 obtains an imaging signal by the imaging device 110, obtains a photometric signal by the photometric sensor 137, obtains a focus detection signal by the focus detection module 160, and a captured image by the display unit 190. Processing for starting each operation of display is performed. In step S102, the camera control unit 170 starts processing for displaying an image based on the imaging signal acquired by the imaging element 110 on the cover unit 190 as a through image.

  In step S103, at the timing when the shutter release button is half-pressed (the first switch SW1 is turned on), the sound characteristics of the external sound input by the sound collecting microphone 140 are stored in the start-up sound storage unit 172 for start-up. Processing for storing the voice characteristics is performed. Specifically, at the timing when the shutter release button is half-pressed, the external sound input by the sound collection microphone 140 is processed by the sound analysis unit 171 by the sound characteristics, that is, volume information, sound waveform information, and Information on the fundamental frequency is extracted. In this case, the time length of the external sound to be extracted from the sound characteristics is not particularly limited, but may be a predetermined time. The voice characteristics of the external voice extracted by the voice analysis unit 171 are stored in the startup voice storage unit 172 as startup voice characteristics.

  In step S104, a timer (not shown) provided in the camera control unit 170 is activated. If the timer has already been started, processing for setting the count value of the timer to zero is performed.

  In step S <b> 105, the camera control unit 170 performs an exposure calculation based on the photometric signal acquired by the photometric sensor 137.

  In step S106, the camera control unit 170 performs a calculation for detecting the focus state of the optical system based on the focus detection signal acquired by the focus detection module 160, and based on the calculation result, the photographing is performed. The focus adjustment of the optical system is performed by driving the focus lens constituting the lens 210.

  In step S107, the camera control unit 170 determines whether the photographer has fully pressed the shutter release button (the second switch SW2 is turned on). When the second switch SW2 is turned on, the process proceeds to step S108. On the other hand, if the second switch SW2 is not turned on, the process proceeds to step S111.

  In step S108, the activation control unit 176 performs processing for causing the image sensor 110 to capture a subject image, whereby the image sensor 110 captures the subject image and outputs an image signal.

  In step S109, a process of storing the image signal output from the image sensor 110 in step S108 in the memory 180 is performed.

  In step S110, at the timing when the shutter release button is fully pressed (second switch SW2 is turned on), the sound characteristics of the external sound input by the sound collecting microphone 140 are stored in the image pickup sound storage unit 174 for image pickup. Processing for storing the voice characteristics is performed. Specifically, at the timing when the shutter release button is fully pressed, the sound analysis unit 171 performs the sound characteristics, that is, the sound volume information, the sound waveform information, and the external sound input from the sound collecting microphone 140. Information on the fundamental frequency is extracted. In this case, the time length of the external sound to be extracted from the sound characteristics is not particularly limited, but may be a predetermined time. Then, the sound characteristics of the external sound extracted by the sound analysis unit 171 are stored in the image pickup sound storage unit 174 as image pickup sound characteristics.

  In step S111, it is determined whether or not the shutter release button is half-pressed (the first switch SW1 is on). If the first switch SW1 is on, the process returns to step S104, and the timer The count value is set to zero, and the processes in steps S105 to S110 are repeated again. On the other hand, if the first switch SW1 is not on, the process proceeds to step S112.

  In step S112, it is determined whether or not the count value of the timer is equal to or greater than a predetermined value (that is, whether or not a predetermined time has elapsed since the first switch was turned off). If the count value of the timer is not equal to or greater than a predetermined value, the process returns to step S105 and the processes of steps S105 to S111 are repeated again. On the other hand, if the count value of the timer is equal to or greater than a predetermined value, the process proceeds to step S113.

  In step S113, the count value of the timer becomes equal to or greater than a predetermined value (because a predetermined time has elapsed since the first switch was turned off), so the image sensor 110, the photometric sensor 137, the focus detection module 160, And the display part 190 is turned off, it transfers to a low power consumption mode, and returns to step S101.

  As described above, in the “sound memory photographing mode”, the sound characteristic of the external sound when the shutter release button is half-pressed is stored in the start-up sound storage unit 172 as the start-up sound characteristic (step S103). In addition, a process of storing the audio characteristics of the external audio when the shutter release button is fully pressed in the imaging audio storage unit 174 as the imaging audio characteristics is performed (step S111).

  Next, an operation example in the case where the “sound detection automatic photographing mode” for automatically starting the photographing preparation operation and photographing of the camera 1 is selected will be described. Here, FIG. 10 is a flowchart showing the operation of the camera 1 when the “sound detection automatic photographing mode” is selected.

  The operation described below is started when the power of the camera 1 is turned on and the “sound detection automatic photographing mode” is selected. The camera 1 of the present embodiment is set to a low power consumption mode (a mode in which the image sensor 110, the photometric sensor 137, the focus detection module 160, and the display unit 190 are turned off) when the power is turned on. Is done.

  First, in step S <b> 201, external sound is input by the sound collection microphone 140.

  In step S202, the voice analysis unit 171 analyzes the external voice input in step S201. Specifically, the sound analysis unit 171 analyzes the sound signal input from the sound collection microphone 140, thereby obtaining the sound characteristics of the external sound, that is, the volume information and sound as shown in FIGS. Extracts waveform information.

In step S203, the first voice characteristic comparison unit 173 compares the external voice characteristic extracted in step S202 with the voice characteristic of the startup voice stored in the startup voice storage unit 172, thereby Then, it is determined whether or not the external voice and the startup voice stored in startup voice storage section 172 match. Specifically, the first voice characteristic comparison unit 173 calculates and calculates the volume difference ΔV and the voice waveform difference ΔW based on the volume and voice waveform of the external voice and the volume and voice waveform of the startup voice. It is determined whether or not the volume difference ΔV is equal to or smaller than a predetermined first volume threshold V ₁ and the calculated voice waveform difference ΔW is equal to or smaller than a predetermined first voice waveform threshold W ₁ . If it is determined that the external voice matches the startup voice stored in the startup voice storage unit 172, the process proceeds to step S204. On the other hand, when it is determined that the external voice and the startup voice stored in the startup voice storage unit 172 do not match, the process returns to step S201 to input the external voice again (step S201), the voice Analysis of the signal (step S202) and determination of whether or not it coincides with the activation voice (step S203) are performed. In other words, in the present embodiment, until the external sound that matches the start-up sound is input, the external sound is input by the sound collecting microphone 140, and the external sound and imaging sound stored in the imaging sound storage unit 174 are recorded. Is repeatedly determined at predetermined time intervals.

  In step S204, since it is determined that the external audio and the activation audio stored in the activation audio storage unit 172 match, the first audio characteristic comparison unit 173 activates the shooting preparation operation of the camera 1. An activation signal for performing the operation is sent to the activation control unit 176, and the activation control unit 176 activates the photographing preparation operation of the camera 1. Specifically, the activation control unit 176 obtains an imaging signal by the imaging device 110, obtains a photometric signal by the photometric sensor 137, obtains a focus detection signal by the focus detection module 160, and a captured image by the display unit 190. Processing for starting each operation of display is performed. In step S102, the camera control unit 170 starts processing for displaying an image based on the imaging signal acquired by the imaging element 110 on the cover unit 190 as a through image.

  In steps S205 to S207, timer activation, exposure calculation, and focus adjustment of the optical system are performed as in steps S104 to S106 shown in FIG.

  In step S <b> 208, external sound is input by the sound collection microphone 140.

  In step S209, in the same manner as in step S202 described above, the sound analysis unit 171 performs the sound characteristics of the external sound input in step S208, that is, volume information and sound waveform information as shown in FIGS. Is extracted.

In step S210, the second audio characteristic comparison unit 175 compares the external audio characteristic extracted in step S209 with the audio characteristic of the imaging audio stored in the imaging audio storage unit 174, thereby Then, it is determined whether or not the external audio and the imaging audio stored in the imaging audio storage unit 174 match. Specifically, the second voice characteristic comparison unit 175 calculates and calculates the volume difference ΔV and the voice waveform difference ΔW based on the volume and voice waveform of the external voice and the volume and voice waveform of the activation voice. volume difference ΔV is at a second volume threshold V ₂ following a predetermined and calculated speech waveform difference ΔW is determined whether it is the second speech waveform threshold W ₂ following predetermined is performed. If it is determined that the external audio and the imaging audio stored in the imaging audio storage unit 174 match, the process proceeds to step S211. On the other hand, if it is determined that the external audio and the activation audio stored in the imaging audio storage unit 174 do not match, the process proceeds to step S213.

  In step S211, since it is determined that the external audio and the imaging audio stored in the imaging audio storage unit 174 match, the second audio characteristic comparison unit 175 causes the camera 1 to perform imaging. An imaging signal is sent to the activation control unit 176. Then, the activation control unit 176 performs processing for causing the image sensor 110 to capture a subject image, whereby the image sensor 110 captures the subject image and outputs an image signal.

  In step S212, a process of storing the image signal output from the image sensor 110 in step S211 in the memory 180 is performed.

  In step S213, it is determined whether or not the count value of the timer is equal to or greater than a predetermined value (that is, whether or not a predetermined time has elapsed since the start of the shooting preparation operation). . If the timer count value is not equal to or greater than the predetermined value, the process returns to step S206, and the processing of steps S206 to S213 is performed until the timer count value is equal to or greater than the predetermined value. Repeatedly. That is, in the present embodiment, until the count value of the timer becomes equal to or greater than a predetermined value, the external sound input by the sound collecting microphone 140 and the external sound and the image pickup sound storage unit 174 are stored. The determination of whether or not the sound for imaging matches is repeated at predetermined time intervals. On the other hand, if the count value of the timer is equal to or greater than a predetermined value, the process proceeds to step S114.

  In step S214, because the count value of the timer becomes equal to or greater than a predetermined value (since a predetermined time has elapsed since the start of the shooting preparation operation), the image sensor 110, the photometric sensor 137, and the focus detection module 160. , And the display unit 190 is turned off, the mode shifts to the low power consumption mode, and the process returns to step S201.

  As described above, in the present embodiment, in the “sound detection automatic shooting mode”, external sound that matches the start-up sound stored in the start-up sound storage unit 172 is input via the sound collection microphone 140. If it is, the camera 1 starts the shooting preparation operation (steps S203 and S204), and the external sound that matches the image pickup sound stored in the image pickup sound storage unit 174 is input to the sound collection microphone 140. When the input is made via, imaging by the camera 1 is performed (steps S210 to S212).

  In the present embodiment, external sound is input via the sound collection microphone 140, and the sound characteristics of the input external sound are compared with the sound characteristics of the start-up sound stored in the start-up sound storage unit 172. When the sound characteristic of the external sound matches the sound characteristic of the start-up sound, a specific external sound is emitted around the camera 1 by configuring the camera 1 to start the shooting preparation operation. In such a case, it is possible to activate the shooting preparation operation of the camera 1 in synchronization with such specific external sound.

  Further, in the present embodiment, when the shooting preparation operation of the camera 1 is activated, external sound is input via the sound collection microphone 140, the sound characteristics of the input external sound, and the imaging sound storage unit By comparing with the sound characteristics of the imaging sound stored in 174, and when the sound characteristics of the external sound match the sound characteristics of the imaging sound, the camera 1 is configured to perform shooting. When a specific external sound is emitted around the camera 1, it is possible to perform shooting by the camera 1 in synchronization with the specific external sound.

  Further, in the present embodiment, the sound characteristics of the external sound when the shutter release button is half-pressed (when the first switch SW1 is turned on) are stored in the start sound storage unit 172 as start sound characteristics, and the shutter The sound characteristics of the external sound when the release button is fully pressed (when the second switch SW2 is turned on) can be stored as the sound characteristics for image capturing in the image capturing sound storage unit 174, thereby registering the desired sound in advance. In addition, it is possible to cause the camera 1 to start the shooting preparation operation and to perform shooting by the camera 1 in synchronization with the desired voice registered in advance.

  FIG. 11 shows an example of a scene to which this embodiment is applied. In FIG. 11, as shown in FIG. 11B, for example, in an automobile race or the like, the car approaches the camera 1 from the position indicated by “α” toward the position indicated by “β”. It shows such a scene. FIG. 11A shows a change in the volume of the driving sound of the automobile input to the camera 1 in the scene shown in FIG. In such a situation, according to the present embodiment, in the “sound recording mode”, when the automobile is in the position indicated by “α” in advance, the shutter button is half-pressed and the automobile is indicated by “α”. The external sound at the time of the position is stored as the start-up sound, and when the vehicle is at the position indicated by “β”, the shutter button is fully pressed and the vehicle is set at the position indicated by “β”. External sound at a certain time can be stored as sound for imaging. In such a case, according to the present embodiment, by setting the “sound detection automatic photographing mode”, when the automobile comes to the position indicated by “α”, the photographing preparation operation of the camera 1 is performed. When the vehicle is activated and then comes to the position indicated by “β”, the camera 1 can perform automatic photographing. In such a car race, it is common that a car other than the car that the photographer wants to shoot also travels on the course. In this embodiment, in addition to the volume of the external sound, When the sound waveform of the voice matches, the camera 1 starts the shooting preparation operation and automatically shoots. Therefore, even in such a scene, the photographer can appropriately shoot the car that the user wants to shoot.

  The embodiment described above is described for facilitating the understanding of the present invention, and is not described for limiting the present invention. Therefore, each element disclosed in the above embodiment is intended to include all design changes and equivalents belonging to the technical scope of the present invention.

For example, in the above-described embodiment, when the first voice characteristic comparison unit 173 determines whether the voice characteristic of the external voice and the voice characteristic of the activation voice match, among these voice characteristics, based on the information of the volume and the voice waveform, and calculates the volume difference ΔV and speech waveform difference [Delta] W, volume difference ΔV is at first volume threshold V ₁ following a predetermined, and the first audio speech waveform difference [Delta] W is given In the case where the waveform threshold W1 is equal to or less than ₁ , the configuration in which it is determined that the voice characteristics of the external voice and the voice characteristics of the startup voice are the same is illustrated. On the other hand, in this embodiment, whether the sound characteristics of the external sound and the sound characteristics of the start-up sound match based on the sound volume difference ΔV and the fundamental frequency instead of the sound volume difference ΔV and the sound waveform difference ΔW. A determination of whether or not may be made. In this case, when the volume difference ΔV is equal to or smaller than a predetermined first volume threshold V ₁ and the basic frequency of the external sound matches the basic frequency of the start-up sound, the sound characteristics of the external sound and the start-up It can be determined that the voice characteristics of the service voice match. Note that not only the first sound characteristic comparison unit 173 but also the second sound characteristic comparison unit 175 replaces the sound volume difference ΔV and the sound waveform difference ΔW with the sound characteristics of the external sound based on the sound volume difference ΔV and the fundamental frequency. Of course, it is possible to determine whether or not the sound characteristics of the imaging sound match.

  In the above-described embodiment, when the shutter release button is fully pressed (second switch SW2 is turned on) in the “sound recording mode”, the sound collection is performed at the timing when the shutter release button is fully pressed. A configuration in which the sound characteristics of the external sound input by the microphone 140 is stored as the sound characteristics for imaging in the imaging sound storage unit 174 is exemplified (step S110 in FIG. 9). On the other hand, in the present embodiment, when the shutter release button is fully pressed (second switch SW2 is turned on) in the “sound recording mode”, the timing from when the shutter release button is fully pressed. A configuration may be adopted in which the sound characteristics of the external sound input before a predetermined time are stored in the image pickup sound storage unit 174 as the image pickup sound characteristics. By adopting such a configuration, it is possible to perform automatic shooting at a timing closer to the timing at which the photographer wants to shoot (timing that substantially matches the timing at which the shooter wants to shoot). In addition, even when the shutter release button is half-pressed (the first switch SW1 is turned on) in the “sound memory shooting mode”, it is input from the timing when the shutter release button is half-pressed to a predetermined time before. The audio characteristic of the external sound may be stored in the activation sound storage unit 172 as the activation sound characteristic.

  Further, in the above-described embodiment, when the shutter release button is half-pressed (first switch SW1 is turned on) and the shutter release button is fully pressed (second switch SW2 is turned on) in the “sound recording mode”. In addition, the configuration in which the audio characteristics of the external audio are stored as the activation audio characteristics and the imaging audio characteristics, respectively, is illustrated. On the other hand, in the present embodiment, for example, the camera 1 is configured to include a voice storage switch in the operation unit 150, and while pressing the voice storage switch, the shutter release button is half-pressed, Or, when the shutter release button is fully pressed, the sound characteristics of the external sound may be stored as the start sound characteristics and the image pickup sound characteristics, respectively. Alternatively, in the present embodiment, external sound is continuously recorded for a predetermined time, the recorded external sound is played back by the camera 1, and the photographer releases the shutter release at a desired timing while listening to the external sound being played back. The sound characteristics of the external sound may be stored as the start sound characteristics and the image pickup sound characteristics by pressing the button halfway or the shutter release button fully.

  In the present embodiment, in the “sound recording mode”, the external sound input by the sound collection microphone 140 is used regardless of whether the shutter release button is half-pressed or the shutter release button is fully pressed. The sound analysis unit 171 is configured to repeatedly extract the sound characteristics, that is, the volume information, the sound waveform information, and the fundamental frequency information at predetermined time intervals, and has an external volume with a predetermined volume or more. When sound is input, the sound characteristics of the external sound having such a predetermined volume or more may be stored as the start sound characteristics or the imaging sound characteristics. FIG. 12 shows an example of a speech analysis method in such a case. 12A and 12B show a sound analysis method when external sound as shown in FIG. 12A is input from the sound collecting microphone 140. FIG. That is, in the example in FIG. 12, external sound having a predetermined time length T1 is repeatedly input at each timing t1, t2, t3, t4, and t5, and the external sound having the predetermined time length T1 is An example in which voice characteristics are extracted by the voice analysis unit 171 is shown. In this case, for example, when an external sound having a predetermined volume or more is input at the time t5, in the present embodiment, the sound of the external sound having a predetermined time length T1 from the time t5 is used. The characteristic can be stored as an activation audio characteristic or an imaging audio characteristic. Alternatively, for example, when an external sound having a predetermined volume or more is input at the time t5, the sound characteristics of the external sound having a predetermined time length T1 from the time t5, for example, a predetermined time before the time t5. May be stored as an activation audio characteristic or an imaging audio characteristic. Further, when such a process is started, the audio is analyzed by the audio analysis unit 171 for the external audio input by the sound collection microphone 140 until the timer is started and the count value of the timer reaches a predetermined value. The characteristic extraction may be repeated at predetermined time intervals, and such a process may be terminated when the count value of the timer reaches a predetermined value or more.

  Note that the imaging apparatus 1 of the present embodiment is not limited to the single-lens reflex digital camera described above, and can also be applied to a lens-integrated digital still camera and video camera. Further, the present invention can also be applied to a small camera module, a surveillance camera, a robot visual recognition device, and the like built in a mobile phone.

DESCRIPTION OF SYMBOLS 1 ... Single-lens reflex digital camera 100 ... Camera body 110 ... Image pick-up element 137 ... Photometric sensor 140 ... Sound collecting microphone 150 ... Operation part 160 ... Focus detection module 170 ... Camera control part 190 ... Display part 200 ... Lens barrel 210 ... Shooting lens 220: Aperture device 230 ... Lens control unit

Claims (12)

Voice input means for inputting external voice from the outside;
Voice analysis means for analyzing the external voice and extracting external voice characteristics which are characteristics of the external voice;
First sound characteristic storage means for storing the characteristic of the first specific sound as the first specific sound characteristic;
An imaging apparatus comprising: a first determination unit that compares the external audio characteristic with the first specific audio characteristic and determines whether or not to start an imaging preparation operation based on the comparison result. . The imaging device according to claim 1,
The external audio characteristic and the first specific audio characteristic include volume information and audio waveform information,
The first determination means calculates the difference between the volume of the external sound and the volume of the first specific sound, and the difference between the sound waveform of the external sound and the sound waveform of the first specific sound, An imaging apparatus, wherein an imaging preparation operation is activated when each of the differences is equal to or less than a predetermined threshold value. The imaging device according to claim 1,
The external audio characteristic and the first specific audio characteristic include volume information and fundamental frequency information,
The first determination means calculates the difference between the volume of the external sound and the volume of the first specific sound, and the difference between the basic frequency of the external sound and the basic frequency of the first specific sound, An imaging apparatus, wherein an imaging preparation operation is activated when each of the differences is equal to or less than a predetermined threshold value. In the imaging device according to any one of claims 1 to 3,
The voice analysis means repeats at a predetermined timing, extracts the external voice characteristics,
The imaging apparatus according to claim 1, wherein the first determination unit repeatedly performs the comparison between the external audio characteristic and the first audio characteristic at a predetermined timing. In the imaging device according to any one of claims 1 to 4,
When the user half-presses the release button, the voice analysis means extracts the external voice characteristics of the external voice input to the voice input means when half-pressed,
The first audio characteristic storage means stores the external audio characteristic as the first specific audio characteristic. In the imaging device according to any one of claims 1 to 5,
Second sound characteristic storage means for storing a second specific sound characteristic different from the first specific sound as a second specific sound characteristic;
A second determination unit that compares the external audio characteristic and the second specific audio characteristic when the shooting preparation operation is activated, and determines whether to perform shooting based on the comparison result; And a photographing apparatus. In the imaging device according to claim 6,
The external audio characteristic and the second specific audio characteristic include volume information and audio waveform information,
The second determination means calculates the difference between the volume of the external sound and the volume of the second specific sound, and the difference between the sound waveform of the external sound and the sound waveform of the second specific sound; An imaging apparatus that performs imaging when each of the differences is equal to or less than a predetermined threshold value. In the imaging device according to claim 6,
The external audio characteristic and the second specific audio characteristic include volume information and fundamental frequency information,
The second determination means calculates the difference between the volume of the external sound and the volume of the second specific sound, and the difference between the basic frequency of the external sound and the basic frequency of the second specific sound, An imaging apparatus that performs imaging when each of the differences is equal to or less than a predetermined threshold value. In the imaging device according to any one of claims 6 to 8,
The voice analysis means repeats at a predetermined timing, extracts the external voice characteristics,
The imaging apparatus according to claim 2, wherein the second determination means repeatedly performs the comparison between the external audio characteristic and the second audio characteristic at a predetermined timing. In the imaging device according to any one of claims 6 to 9,
When the user half-presses the release button, the voice analysis means extracts the external voice characteristics of the external voice input to the voice input means when half-pressed,
The second audio characteristic storage means stores the external audio characteristic as the second specific audio characteristic. In the imaging device according to any one of claims 6 to 10,
When the user fully presses the release button, the voice analysis means extracts the external voice characteristics of the external voice input to the voice input means up to a predetermined time before the full press time,
The second audio characteristic storage means stores the external audio characteristic as the second specific audio characteristic. In the imaging device according to any one of claims 6 to 11,
Recording means for recording external sound input from the sound input means by a user operation;
Of external sounds recorded in the external sound recording means by a user's operation, a sound to be stored as a first specific sound characteristic in the first sound characteristic storage means and / or a second specific in the second sound characteristic storage means An imaging apparatus, further comprising setting means for setting a sound to be stored as a sound characteristic.

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