JP2006301151A - Electronic camera - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To properly display both the photographing sensitivity automatically changed in the automatic sensitivity change mode and the sensitivity before changed in an electronic camera. <P>SOLUTION: The electronic camera displays the controlled imaging sensitivity on the display 1091 in the view finder after exposure calculation when the sensitivity switch SW4 is turned on. When the imaging sensitivity is automatically changed in the exposure calculation processing, it flashes "ISO Auto" and displays the imaging sensitivity automatically changed by lighting on the display 1091 in the view finder. When the imaging sensitivity is not automatically changed in the exposure calculation processing, it flashes "ISO Auto" and displays the controlled imaging sensitivity (= setup imaging selectivity) by lighting on the display 1091 in the view finder. When the automatic sensitivity change mode is canceled, it displays the controlled imaging sensitivity (= setup imaging selectivity) by lighting on the display 1091 in the view finder. The electronic camera displays the setup imaging sensitivity on the outside display 1092 when the sensitivity switch SW4 is turned on. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an electronic camera having an operation mode for automatically changing imaging sensitivity.

  An electronic camera that automatically changes imaging sensitivity (exposure sensitivity) is known (see Patent Document 1). The electronic camera described in Patent Document 1 determines the aperture value, shutter speed, and imaging sensitivity according to subject brightness when the imaging sensitivity is set to be changeable (referred to as automatic sensitivity change mode). . The imaging sensitivity is automatically changed so as to approach the proper exposure when the proper exposure is not obtained even when the shutter speed and the aperture value reach the control limits. When the imaging sensitivity is automatically changed, the value after the automatic change is displayed on the camera display device. When the imaging sensitivity is not automatically changed, the camera display device is not automatically changed. The value of is displayed. The imaging sensitivity value before being automatically changed is an imaging sensitivity value set in the camera.

JP 2003-189175 A

  Even when the imaging sensitivity value after the automatic change is displayed, it may be desired to know the imaging sensitivity value before the automatic change. In this case, it is desired to display appropriately without complicating the display mode of the display device. Patent Document 1 does not disclose a specific display mode in this regard.

The electronic camera according to the first aspect of the present invention performs an exposure calculation using an imaging device that captures a subject image and an exposure sensitivity set in the imaging device, and when the appropriate exposure cannot be obtained by the exposure calculation. An exposure calculation unit that calculates the control exposure by changing the exposure sensitivity set to be close to the appropriate exposure, and displays the changed exposure sensitivity in response to the exposure calculation unit changing the exposure sensitivity. And a display means.
An electronic camera according to a second aspect of the invention is set in an imaging device that captures a subject image, an exposure sensitivity display operation member that outputs an operation signal for displaying the exposure sensitivity of the imaging device, and the imaging device. Exposure calculation means that calculates exposure using exposure sensitivity, and changes the exposure sensitivity that is set to be close to the appropriate exposure when appropriate exposure cannot be obtained by the exposure calculation, and exposure sensitivity And a display unit for displaying the exposure sensitivity after the calculation by the exposure calculation unit in response to the output of the operation signal from the display operation member.
3. The electronic camera according to claim 1, wherein the display means may be constituted by an internal display device provided in the viewfinder, and an exposure sensitivity setting for outputting an operation signal for setting the exposure sensitivity of the imaging device. An operation member, and an external display device that is provided in the camera casing and displays an exposure sensitivity set by the operation signal in response to an operation signal output from the exposure sensitivity setting operation member. You may make it prepare.

  The electronic camera according to the present invention can appropriately display the imaging sensitivity automatically changed by the exposure calculation and the imaging sensitivity before the change without complicating the display mode.

  The best mode for carrying out the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing a configuration of an electronic camera according to an embodiment of the present invention. In FIG. 1, an arithmetic circuit 101 is configured by a microcomputer or the like. The arithmetic circuit 101 inputs a signal output from each block to be described later, performs a predetermined calculation, and outputs a control signal to each block based on the calculation result. The image sensor 121 is configured by a CCD image sensor or the like. The image sensor 121 captures a subject image by light that has passed through the photographing lens L, and outputs an image signal to the A / D conversion circuit 122.

  The A / D conversion circuit 122 converts the analog imaging signal into a digital signal. The image sensor 121 and the A / D conversion circuit 122 are driven at a predetermined timing by a drive signal output from the timing circuit 124.

  The imaging element 121 is configured to be able to change imaging sensitivity (exposure sensitivity) in a predetermined step within a range corresponding to ISO 100 to ISO 1600 when setting an automatic sensitivity change mode to be described later. The imaging sensitivity is a controlled amount that changes the detection sensitivity of charges accumulated in the imaging element 121 or the amplification gain of an amplifier circuit (not shown). The imaging sensitivity is represented by a corresponding ISO sensitivity value.

  The ASIC 123 constituting the imaging signal processing circuit performs predetermined image processing on the signal after digital conversion. The image processing includes white balance (WB) adjustment processing, compression processing for compressing image data in a predetermined format, and decompression processing for decompressing data after the compression processing. The buffer memory 125 sequentially inputs the image data signal-processed by the ASIC 123 and temporarily stores the data. The recording medium 126 is configured by a removable flash memory or the like. The recording medium 126 records image data temporarily stored in the buffer memory 125.

  The exposure mode switch SW3 is turned on in conjunction with a pressing operation of an exposure mode setting button (not shown), and outputs an on signal to the arithmetic circuit 101. On the other hand, the exposure mode switch SW3 is turned off in conjunction with release of the exposure mode setting button. Is output to the arithmetic circuit 101. When an operation signal is input from a main command dial 110 (to be described later) in a state where an ON signal is input from the exposure mode switch SW3, the arithmetic circuit 101 performs a program auto exposure calculation mode (P) and shutter speed priority according to the operation signal. The exposure calculation mode (S), the aperture value priority exposure calculation mode (A), and the manual exposure mode (M) are set.

  In the program auto exposure calculation mode, the control exposure is calculated by changing the exposure time and aperture value of the image sensor 121 in a predetermined combination so that an appropriate exposure can be obtained. In the shutter speed (exposure time) priority exposure calculation mode, the control exposure is calculated by changing the aperture value so that an appropriate exposure can be obtained with the set exposure time. In the aperture value priority exposure calculation mode, the control exposure is calculated by changing the exposure time so that an appropriate exposure can be obtained with the set aperture value. In the manual exposure mode, the deviation between the control exposure and the appropriate exposure according to the set exposure time and aperture value is calculated.

  The main command dial 110 outputs an operation signal indicating the rotation direction and the rotation amount to the arithmetic circuit 101 according to the rotation operation. The subcommand dial 111 outputs an operation signal indicating the rotation direction and the rotation amount to the arithmetic circuit 101 according to the rotation operation.

  The sensitivity automatic change mode setting operation member 112 is an operation member for setting / releasing the sensitivity automatic change mode. The sensitivity automatic change mode setting operation member 112 outputs an operation signal corresponding to the setting / cancellation operation to the arithmetic circuit 101. The arithmetic circuit 101 sets or cancels the automatic sensitivity change mode according to the input operation signal. When the automatic sensitivity change mode is set, the control exposure is calculated by automatically changing the imaging sensitivity according to the exposure deviation ΔEV so as to approach the appropriate exposure. The exposure deviation ΔEV is a deviation between the control exposure and the appropriate exposure. When the automatic sensitivity change mode is cancelled, the control exposure is calculated so that a proper exposure can be obtained with the set imaging sensitivity.

  The sensitivity setting switch SW4 is turned on in conjunction with a pressing operation of an imaging sensitivity setting button (not shown) and outputs an on signal to the arithmetic circuit 101. On the other hand, the sensitivity setting switch SW4 is turned off in conjunction with release of the imaging sensitivity setting button. Is output to the arithmetic circuit 101. When the operation signal is input from the main command dial 110 in a state where the ON signal is input from the sensitivity setting switch SW4, the arithmetic circuit 101 changes the setting value of the imaging sensitivity of the image sensor 121 described above according to the operation signal. . The setting range of the set imaging sensitivity SVs can be set within a range of, for example, 5 ≦ SVs ≦ 9, that is, an ISO 100 equivalent to an ISO 1600 equivalent.

  The photometric device 102 detects the amount of light transmitted through the photographing lens L and outputs a detection signal to the arithmetic circuit 101. The arithmetic circuit 101 calculates the brightness of the subject using the detection signal from the photometric device 102.

  The shutter control circuit 103 controls the holding and release of a front curtain and a rear curtain (not shown) of the shutter 104, respectively.

  The motor control circuit 105 controls the rotation of the sequence motor 106 according to a command from the arithmetic circuit 101. The sequence motor 106 is incorporated in a sequence driving device (not shown), and performs up / down of a mirror (not shown), narrowing / opening of a diaphragm (not shown), charging of the shutter 104, and the like.

  The sequence switch SW1 constitutes the above sequence drive device, and generates a signal indicating drive of the sequence motor 106, brake control timing, and the like.

  The aperture position detection device 107 detects the aperture position corresponding to the aperture value and outputs a detection signal to the arithmetic circuit 101. The aperture locking device 108 locks the aperture being driven and stops the aperture at a predetermined aperture value.

  The display device 109 displays the exposure mode, shutter speed, aperture value, number of frames that can be shot, imaging sensitivity, and the like set in the electronic camera according to instructions from the arithmetic circuit 101. The display device 109 includes an in-finder display device 1091 and an external display device 1092 provided in the camera casing. FIG. 2 is a diagram illustrating a display segment of the in-finder display device 1091, and FIG. 3 is a diagram illustrating a display segment of the external display device 1092.

  The release switch SW2 is turned on in conjunction with a pressing operation of a release button (not shown) and outputs an on signal to the arithmetic circuit 101. The release switch SW2 is turned off in conjunction with release release of the release button, and outputs an off signal to the arithmetic circuit 101.

  The electronic camera according to the present embodiment relates to the display operation by the display device 109. In particular, the imaging sensitivity automatically changed in the state set in the sensitivity automatic change mode, and the operation signal from the sensitivity setting switch SW4 and the main command dial 110. The imaging sensitivity set in the electronic camera is appropriately displayed.

(Main process)
A flow of camera operation processing performed by the arithmetic circuit 101 of the electronic camera according to the present embodiment will be described with reference to a flowchart of FIG. The program according to the flowchart of FIG. 4 is activated when a battery (not shown) is loaded in the electronic camera. In step S1 of FIG. 4, the arithmetic circuit 101 performs the following initial settings. That is, the set imaging sensitivity SVs is set to 7 (corresponding to ISO 400), the set shutter speed TVs is set to 7 (1/125 seconds), the set aperture value AVs is set to 5 (F5.6), the mode parameter M is set to 1, and the sensitivity is set. The automatic change mode flag S is set to 0, and the process proceeds to step S2. For SVs, TVs, and AVs, apex values are used.

  The exposure mode parameter M is set to 1 when the electronic camera is set to the programmed auto exposure calculation mode (P), and is set to 2 when the shutter speed priority (exposure time priority) exposure calculation mode (S) is set. These parameters are set to 3 when the exposure calculation mode (A) is set and 4 when the manual exposure mode (M) is set. The automatic sensitivity change mode flag S is a flag that is set to 1 when the electronic camera is set to the automatic sensitivity change mode, and is set to 0 when the automatic sensitivity change mode is canceled.

In step S2, the arithmetic circuit 101 calculates the lens transmitted light amount (BV-AV ₀ ) based on the detection signal input from the photometric device 102, performs photometry for calculating the subject luminance BV using the calculated value, and step S3. Proceed to The subject brightness BV can be obtained by adding the open aperture value AV ₀ to the lens transmitted light amount (BV−AV ₀ ). In this embodiment, AV ₀ = 3, that is, F2.8.

  In step S3, the arithmetic circuit 101 performs exposure calculation processing and proceeds to step S4. Details of the exposure calculation process will be described later. In step S4, the arithmetic circuit 101 performs a display process on the display device 109 and proceeds to step S5. Details of the display process will be described later.

  In step S5, the arithmetic operation circuit 101 performs a setting process and proceeds to step S6. Details of the setting process will be described later. In step S6, the arithmetic circuit 101 performs display processing on the display device 109 again, and proceeds to step S7.

  In step S7, the arithmetic circuit 101 determines whether or not a release operation has been performed. The arithmetic operation circuit 101 makes an affirmative determination in step S7 when an on signal is input from the release switch SW2 and proceeds to step S8. If an on signal is not input from the release switch SW2, the arithmetic circuit 101 makes a negative determination in step S7 and performs step S2. Return to.

  In step S8, the arithmetic circuit 101 performs a release sequence process and returns to step S2. Details of the release sequence process will be described later. As a result, a series of photographing processes is completed.

(Exposure calculation processing)
Details of the exposure calculation processing will be described with reference to the flowcharts of FIGS. In step S101 of FIG. 5, the arithmetic circuit 101 calculates EV = BV + SVs using the subject luminance BV calculated based on the lens transmitted light amount (BV−AV ₀ ) in step S2, and then proceeds to step S102. Here, EV is an exposure value. The set imaging sensitivity SVs is an imaging sensitivity set by operation signals from the sensitivity setting switch 104 and the main command dial 110.

  In step S102, the arithmetic operation circuit 101 makes a decision as to whether or not the exposure mode parameter M = 1. The arithmetic operation circuit 101 makes an affirmative decision in step S102 if M = 1 (programmed auto exposure calculation mode (P) is set), and proceeds to step S103. If M ≠ 1, a negative decision is made in step S102. Then, the process proceeds to step S141 in FIG.

(Program auto exposure calculation)
After step S103, a program auto exposure calculation process is performed. In step S103, the arithmetic operation circuit 101 calculates AVc = EV / 2-1 and proceeds to step S104. Here, AVc is a control aperture value. In step S104, the arithmetic operation circuit 101 makes a decision as to whether AVc <3 holds. The arithmetic operation circuit 101 makes an affirmative decision in step S104 when AVc <3 is satisfied (the aperture diameter based on the control aperture value is larger than the aperture diameter of F2.8), proceeds to step S105, and when AVc <3 is not satisfied. Makes a negative determination in step S104 and proceeds to step S108. F2.8 is the control limit of this embodiment. In step S105, the arithmetic operation circuit 101 sets the control aperture value AVc to 3 before proceeding to step S106. Thereby, the control aperture value is set to the lower limit of the control range.

  In step S106, the arithmetic operation circuit 101 calculates TVc = EV-3 and proceeds to step S112. Here, TVc is the control shutter speed.

  In step S108, the arithmetic operation circuit 101 makes a decision as to whether AVc> 9 holds. The arithmetic operation circuit 101 makes an affirmative decision in step S108 when AVc> 9 is satisfied (the aperture diameter based on the control aperture value is smaller than the aperture diameter of F22), and proceeds to step S109. If AVc> 9 is not satisfied, the arithmetic circuit 101 proceeds to step S109. A negative determination is made in S108, and the process proceeds to Step S111. F22 is the control limit of this embodiment. In step S109, the arithmetic operation circuit 101 sets the control aperture value AVc to 9 before proceeding to step S110. Thereby, the control aperture value is set to the upper limit of the control range.

  In step S110, the arithmetic operation circuit 101 calculates TVc = EV-9 and proceeds to step S112. Here, TVc is the control shutter speed.

  In step S111, the arithmetic operation circuit 101 calculates TVc = EV−AVc and proceeds to step S112. Here, TVc is the control shutter speed.

  In step S112, the arithmetic operation circuit 101 makes a decision as to whether TVc <0 holds. The arithmetic operation circuit 101 makes an affirmative decision in step S112 when TVc <0 is established (the control shutter speed is slower than 1 second), and proceeds to step S113. If TVc <0 is not established, the operation circuit 101 makes a negative decision in step S112. Then, the process proceeds to step S114. One second is the control limit of this embodiment. In step S113, the arithmetic operation circuit 101 sets 0 for the control shutter speed TVc before proceeding to step S116. Thereby, the control shutter speed is set to the lower limit of the control range.

  In step S114, which proceeds after making a negative determination in step S112, the arithmetic operation circuit 101 determines whether or not TVc> 10 holds. The arithmetic operation circuit 101 makes an affirmative decision in step S114 when TVc> 10 is established (the control shutter speed is higher than 1/1000 second), and proceeds to step S115. If TVc> 10 is not established, the operation circuit 101 negates step S114. Determine and proceed to step S116. 1/1000 second is the control limit of this embodiment. In step S115, the arithmetic operation circuit 101 sets 10 for the control shutter speed TVc before proceeding to step S116. Thereby, the control shutter speed is set to the upper limit of the control range.

  In step S116, the arithmetic operation circuit 101 makes a decision as to whether or not the sensitivity automatic change mode flag S = 1. The arithmetic operation circuit 101 makes an affirmative decision in step S116 when S = 1 (set to the automatic sensitivity change mode) and proceeds to step S121 in FIG. 6, and if S = 0 (cancels the automatic sensitivity change mode), the operation circuit 101 proceeds to step S121. A negative determination is made in S116, and the process proceeds to Step S117.

  In step S117, the arithmetic operation circuit 101 sets the set imaging sensitivity SVs as the control imaging sensitivity SVc before proceeding to step S118. In step S118, the arithmetic circuit 101 sets 0 in the flag C, ends the processing in FIG. 5, and proceeds to step S4 in FIG. Here, the flag C is a flag that is set to 1 when the imaging sensitivity is changed from the set imaging sensitivity SVs (SVc ≠ SVs), and is set to 0 when the imaging sensitivity is not changed from the set imaging sensitivity SVs (SVc = SVs).

In step S121 of FIG. 6 that proceeds when the automatic sensitivity change mode is set, the arithmetic operation circuit 101 calculates the exposure deviation ΔEV by the following equation (1), and the operation proceeds to step S122.
ΔEV = AVc + TVc−EV (1)
However, (AVc + TVc) is a control exposure, and EV is a proper exposure.

  In step S122, the arithmetic operation circuit 101 determines whether or not | ΔEV | <δ holds. δ is a predetermined value equal to or less than ½, which is set to 1/6 here. If | ΔEV | <δ holds, the arithmetic operation circuit 101 makes an affirmative decision in step S122 and proceeds to step S124. If | ΔEV | <δ does not hold, the operation circuit 101 makes a negative determination in step S122 and proceeds to step S123. The process proceeds to step S124 when the control exposure can be regarded as the proper exposure, and the process proceeds to step S123 when the proper exposure cannot be obtained.

  In step S123, the arithmetic operation circuit 101 calculates SVc = SVs + ΔEV and proceeds to step S125. Thereby, it is possible to obtain the control imaging sensitivity changed from the set imaging sensitivity so as to obtain an appropriate exposure.

  In step S125, the arithmetic operation circuit 101 makes a decision as to whether or not SVc> 9 holds. The arithmetic operation circuit 101 makes an affirmative decision in step S125 when SVc> 9 is established (the control imaging sensitivity is higher than that equivalent to ISO 1600), and proceeds to step S126. If SVc> 9 is not established, the arithmetic circuit 101 makes a negative decision in step S125. Then, the process proceeds to step S127. ISO 1600 is a control limit of this embodiment. In step S126, the arithmetic operation circuit 101 sets 9 for the control sensitivity SVc before proceeding to step S129. Thereby, the control imaging sensitivity is set to the upper limit of the control range.

  In step S127, which proceeds after making a negative determination in step S125 described above, the arithmetic operation circuit 101 determines whether or not SVc <5 is satisfied. The arithmetic operation circuit 101 makes an affirmative decision in step S127 when SVc <5 is established (the control imaging sensitivity is lower than that equivalent to ISO 100), and proceeds to step S128. If SVc <5 is not established, the operation circuit 101 makes a negative decision in step S127. Then, the process proceeds to step S129. ISO 100 is the control limit of this embodiment. In step S128, the arithmetic operation circuit 101 sets 5 for the control sensitivity SVc before proceeding to step S129. Thereby, the control imaging sensitivity is set to the lower limit of the control range.

  In step S129, the arithmetic operation circuit 101 makes a decision as to whether or not SVc = SVs. If SVc = SVs is satisfied, the arithmetic operation circuit 101 makes an affirmative decision in step S129 and proceeds to step S130. If SVc = SVs does not hold, the operation circuit 101 makes a negative determination in step S129 and proceeds to step S131. In step S130, the arithmetic circuit 101 sets the flag C to 0, ends the processing of FIG. 6, and proceeds to step S4 of FIG. In step S131, the arithmetic circuit 101 sets the flag C to 1, ends the processing of FIG. 6, and proceeds to step S4 of FIG.

  In step S141 in FIG. 7 which proceeds after making a negative determination in step S102 in FIG. 5, the arithmetic operation circuit 101 determines whether or not the exposure mode parameter M = 2. The arithmetic operation circuit 101 makes an affirmative decision in step S141 when M = 2 (set to the shutter speed priority exposure calculation mode (S)), and proceeds to step S142. If M ≠ 2, the operation circuit 101 denies step S141. Determination is made and the process proceeds to step S148.

(Shutter speed priority exposure calculation)
After step S142, shutter speed priority exposure calculation is performed. In step S142, the arithmetic operation circuit 101 sets the set shutter speed TVs as the control shutter speed TVc, and then proceeds to step S143. In step S143, the arithmetic operation circuit 101 calculates AVc = EV−TVc and proceeds to step S144. Here, AVc is a control aperture value.

  In step S144, the arithmetic operation circuit 101 makes a decision as to whether AVc <3 is satisfied. The arithmetic operation circuit 101 makes an affirmative decision in step S144 when AVc <3 is satisfied (the aperture diameter based on the control aperture value is larger than the aperture diameter of F2.8), and proceeds to step S145, and when AVc <3 is not satisfied. Makes a negative determination in step S144 and proceeds to step S146. In step S145, the arithmetic operation circuit 101 sets the control aperture value AVc to 3 before proceeding to step S116 in FIG. Thereby, the control aperture value is set to the lower limit of the control range. Step S116 and subsequent steps are common to the case of programmed auto exposure calculation.

  In step S146, the arithmetic operation circuit 101 makes a decision as to whether AVc> 9 holds. The arithmetic operation circuit 101 makes an affirmative decision in step S146 when AVc> 9 is satisfied (the aperture diameter based on the control aperture value is smaller than the aperture diameter of F22), and proceeds to step S147. A negative determination is made in S146, and the process proceeds to Step S116 in FIG. In step S147, the arithmetic operation circuit 101 sets the control aperture value AVc to 9 before proceeding to step S116 in FIG. Thereby, the control aperture value is set to the upper limit of the control range.

  In step S148, which proceeds after making a negative determination in step S141 described above, the arithmetic operation circuit 101 determines whether or not the exposure mode parameter M = 3. The arithmetic operation circuit 101 makes an affirmative decision in step S148 when M = 3 (set to the aperture value priority exposure operation mode (A)), and proceeds to step S149. If M ≠ 3, the operation circuit 101 negates step S148. Determine and proceed to step S155.

(Aperture value priority exposure calculation)
After step S149, aperture value priority exposure calculation processing is performed. In step S149, the arithmetic operation circuit 101 sets the set aperture value AVs as the control aperture value AVc before proceeding to step S150. In step S150, the arithmetic operation circuit 101 calculates TVc = EV−AVc and proceeds to step S151. Here, TVc is the control shutter speed.

  In step S151, the arithmetic operation circuit 101 determines whether TVc <0 is satisfied. The arithmetic operation circuit 101 makes an affirmative decision in step S151 when TVc <0 is established (the control shutter speed is slower than 1 second), and proceeds to step S152. If TVc <0 is not established, the operation circuit 101 makes a negative decision in step S151. Then, the process proceeds to step S153. In step S152, the arithmetic operation circuit 101 sets 0 for the control shutter speed TVc and then proceeds to step S116 in FIG. Thereby, the control shutter speed is set to the lower limit of the control range. Step S116 and subsequent steps are common to the case of programmed auto exposure calculation.

  In step S153, which proceeds after making a negative determination in step S151, the arithmetic operation circuit 101 determines whether or not TVc> 10 holds. The arithmetic operation circuit 101 makes an affirmative decision in step S153 when TVc> 10 is established (the control shutter speed is higher than 1/1000 second), and proceeds to step S154. If TVc> 10 is not established, the operation circuit 101 negates step S153. Determination is made and the process proceeds to step S116 in FIG. In step S154, the arithmetic operation circuit 101 sets 10 for the control shutter speed TVc and proceeds to step S116 in FIG. Thereby, the control shutter speed is set to the upper limit of the control range.

(Manual exposure calculation)
After step S155, manual exposure calculation processing is performed. In step S155, the arithmetic operation circuit 101 sets the set shutter speed TVs as the control shutter speed TVc, and then proceeds to step S156. In step S156, the arithmetic operation circuit 101 sets the set aperture value AVs as the control aperture value AVc and proceeds to step S116 in FIG. Step S116 and subsequent steps are common to the case of programmed auto exposure calculation.

(Display processing)
Details of the display process will be described with reference to the flowchart of FIG. In step S161 in FIG. 8, the arithmetic operation circuit 101 sends commands to the in-finder display device 1091 and the external display device 1092 to light up and display the set exposure mode, control shutter speed TVc, and control aperture value AVc. Then, the process proceeds to step S162. Each of the in-finder display device 1091 and the external display device 1092 has a character or mark (for example, any one of “P”, “S”, “A”, “M”) corresponding to the set exposure mode, The shutter speed and aperture value corresponding to the apex value are displayed.

  FIG. 9 is a diagram exemplifying display contents by the in-finder display device 1091. In FIG. 9, the display segment “A” 91 indicating the exposure mode, the display segment “125” 92 indicating the shutter speed (1/125 seconds), and the display segment “F5.6” 93 indicating the aperture value are respectively lit and displayed. ing.

  FIG. 10 is a diagram illustrating contents displayed by the external display device 1092. In FIG. 10, the display segment “A” 101 indicating the exposure mode, the display segment “125” 102 indicating the shutter speed (1/125 seconds), and the display segment “F5.6” 103 indicating the aperture value are respectively lit and displayed. ing.

  In step S162 of FIG. 8, the arithmetic operation circuit 101 makes a decision as to whether or not the automatic sensitivity change mode flag S = 1. The arithmetic operation circuit 101 makes an affirmative decision in step S162 when S = 1 (set to the automatic sensitivity change mode) and proceeds to step S163, and negates step S162 when S = 0 (the automatic sensitivity change mode is canceled). The process shown in FIG. After the process in FIG. 8, if the setting process (step S5) in FIG. 4 is before the process, the process proceeds to step S5, and if the setting process (step S5) has been completed, the process proceeds to step S7.

  In step S163, the arithmetic operation circuit 101 makes a decision as to whether or not flag C = 1. The arithmetic operation circuit 101 makes an affirmative decision in step S163 when C = 1 (the imaging sensitivity is changed from the set imaging sensitivity SVs in the automatic sensitivity change mode), and proceeds to step S164, where C = 0 (imaging sensitivity is set imaging). If the sensitivity SVs has not been changed), a negative determination is made in step S163, and the process proceeds to step S165.

  In step S164, the arithmetic operation circuit 101 sends a command to each of the in-finder display device 1091 and the external display device 1092 to blink the “ISO Auto” character or mark, and the processing in FIG. After the process in FIG. 8, if the setting process (step S5) in FIG. 4 is before the process, the process proceeds to step S5, and if the setting process (step S5) has been completed, the process proceeds to step S7.

  FIG. 11 is a diagram exemplifying display contents by the display device 1091 in the viewfinder. In addition to the display content illustrated in FIG. 9, the display segment “ISO Auto” 94A is displayed blinking, indicating that the control imaging sensitivity SVc has been changed from the set imaging sensitivity SVs by the exposure calculation process. The shutter speed is changed to the low speed limit by the exposure calculation process, and the display segment “1” ”92A indicating (1 second) is lit.

  FIG. 12 is a diagram illustrating contents displayed by the external display device 1092. In addition to the display content illustrated in FIG. 10, the display segment “ISO Auto” 104A blinks to indicate that the control imaging sensitivity SVc is automatically changed from the set imaging sensitivity SVs by the exposure calculation process. The shutter speed is changed to the low speed limit by the exposure calculation process, and the display segment “1” ”102A indicating (1 second) is lit.

  In step S165, the arithmetic operation circuit 101 sends a command to each of the in-finder display device 1091 and the external display device 1092 to light up and display the character or mark “ISO Auto”, and the processing in FIG. After the process in FIG. 8, if the setting process (step S5) in FIG. 4 is before the process, the process proceeds to step S5, and if the setting process (step S5) has been completed, the process proceeds to step S7.

  FIG. 13 is a diagram exemplifying display contents by the display device 1091 in the finder. In addition to the display content illustrated in FIG. 9, the display segment “ISO Auto” 94 is lit.

  FIG. 14 is a diagram illustrating contents displayed by the external display device 1092. In addition to the display content illustrated in FIG. 10, the display segment “ISO Auto” 104 is lit.

(Setting process)
Details of the setting process will be described with reference to the flowcharts of FIGS. 15, 16, and 17. In step S171 in FIG. 15, the arithmetic operation circuit 101 makes a decision as to whether or not the sensitivity setting switch SW4 has been turned on. The arithmetic operation circuit 101 makes an affirmative decision in step S171 when an on signal is input from the sensitivity setting switch SW4, and proceeds to step S172. If an on signal is not input from the sensitivity setting switch SW4, the arithmetic operation circuit 101 denies step S171. The determination is made, and the process proceeds to step S191 in FIG.

  In step S172, the arithmetic operation circuit 101 makes a decision as to whether or not the main command dial 110 has been rotated counterclockwise. The arithmetic operation circuit 101 makes an affirmative decision in step S172 when an operation signal indicating counterclockwise rotation is input from the main command dial 110 and proceeds to step S173. If an operation signal indicating counterclockwise rotation is not input, the arithmetic operation circuit 101 proceeds to step S172. Is negatively determined, and the process proceeds to step S175.

  In step S173, the arithmetic operation circuit 101 makes a decision as to whether SVs = 9. The arithmetic operation circuit 101 makes an affirmative decision in step S173 when SVs = 9 (the set imaging sensitivity is equivalent to ISO 1600), and proceeds to step S178. In this case, since the upper limit of the imaging sensitivity setting range, the sensitivity is not further increased. On the other hand, if SVs ≠ 9, the arithmetic operation circuit 101 makes a negative determination in step S173 and proceeds to step S174. In step S174, the arithmetic operation circuit 101 adds 1 to the set imaging sensitivity SVs and proceeds to step S178. As a result, the set imaging sensitivity SVs is changed by one step.

  In step S175, the arithmetic operation circuit 101 determines whether or not the main command dial 110 has been rotated clockwise. The arithmetic operation circuit 101 makes an affirmative decision in step S175 when the operation signal indicating the clockwise rotation is input from the main command dial 110, and proceeds to step S176. If the operation signal indicating the clockwise rotation is not input, the arithmetic circuit 101 negates the step S175. Determine and proceed to step S178.

  In step S176, the arithmetic operation circuit 101 makes a decision as to whether SVs = 5. The arithmetic operation circuit 101 makes an affirmative decision in step S176 when SVs = 5 (the set imaging sensitivity is equivalent to ISO 100), and proceeds to step S178. In this case, since the lower limit of the imaging sensitivity setting range, the sensitivity is not further reduced. On the other hand, when SVs ≠ 5, the arithmetic operation circuit 101 makes a negative determination in step S176 and proceeds to step S177. In step S177, the arithmetic operation circuit 101 subtracts 1 from the set imaging sensitivity SVs before proceeding to step S178. As a result, the set imaging sensitivity SVs is changed by one step.

  In step S178, the arithmetic operation circuit 101 performs photometry in the same manner as in step S2 (FIG. 4), and proceeds to step S179. In step S179, the arithmetic operation circuit 101 performs an exposure operation in the same manner as in step S3 (FIG. 4), and proceeds to step S180.

  In step S180, the arithmetic operation circuit 101 sends a command to the external display device 1092 to light up and display “ISO” characters or marks and the set imaging sensitivity SVs, and then the operation proceeds to step S181. The external display device 1092 displays “ISO” and the imaging sensitivity corresponding to the apex value. FIG. 18 is a diagram illustrating contents displayed by the external display device 1092. In FIG. 18, the display segment “ISO” 181 is lit up to indicate that the imaging sensitivity changing operation is being performed, and the display segment “8oo” 182 is lit up to indicate that the set imaging sensitivity is equivalent to ISO 800. Show. Other display segments are hidden.

  In step S181, the arithmetic operation circuit 101 makes a decision as to whether or not the sensitivity automatic change mode flag S = 1. The arithmetic operation circuit 101 makes an affirmative decision in step S181 when S = 1 (set to the automatic sensitivity change mode) and proceeds to step S182, and deny step S181 if S = 0 (the automatic sensitivity change mode is canceled). Determination is made and the process proceeds to step S185.

  In step S182, the arithmetic operation circuit 101 makes a decision as to whether or not flag C = 1. The arithmetic operation circuit 101 makes an affirmative decision in step S182 when C = 1 (the imaging sensitivity is changed from the set imaging sensitivity SVs in the automatic sensitivity change mode), and proceeds to step S183, where C = 0 (imaging sensitivity is set imaging). If the sensitivity SVs has not been changed), a negative determination is made in step S182, and the process proceeds to step S184.

  In step S183, the arithmetic operation circuit 101 sends a command to the in-finder display device 1091 to blink the “ISO Auto” character or mark and to turn on the control imaging sensitivity SVc, and then proceeds to step S186. The in-finder display device 1091 blinks “ISO Auto” and lights up the imaging sensitivity corresponding to the apex value. FIG. 19 is a diagram illustrating contents displayed by the in-finder display device 1091. In FIG. 19, the display segment “ISO Auto” 94A blinks to indicate that the control imaging sensitivity SVc is automatically changed from the set imaging sensitivity SVs by the exposure calculation process. In addition, the display segment “16oo” 191A indicating the changed control imaging sensitivity SVc (equivalent to ISO 1600) is lit on and the other display segments are not displayed.

  In step S184, the arithmetic operation circuit 101 sends a command to the in-finder display device 1091 to display the “ISO Auto” character or mark and the control imaging sensitivity SVc in a lighting manner, and then the operation proceeds to step S186. The in-finder display device 1091 lights and displays “ISO Auto” and the imaging sensitivity corresponding to the apex value. FIG. 20 is a diagram illustrating contents displayed by the in-finder display device 1091. In FIG. 20, the display segment “ISO Auto” 94 and the display segment “8oo” 191 indicating the control imaging sensitivity SVc (equivalent to ISO 800) are lit on, and the other display segments are not displayed. In this case, the control imaging sensitivity SVc is equal to the set imaging sensitivity SVs.

  In step S185, the arithmetic operation circuit 101 sends a command to the in-finder display device 1091 to turn on the set imaging sensitivity SVs, and then the operation proceeds to step S186. The in-finder display device 1091 lights up and displays the imaging sensitivity corresponding to the apex value. FIG. 21 is a diagram illustrating contents displayed by the in-finder display device 1091. In FIG. 21, the display segment “8oo” 191 indicating the set imaging sensitivity SVs (equivalent to ISO 800) is lit on and the other display segments are not displayed. In this case, the control imaging sensitivity SVc is equal to the set imaging sensitivity SVs.

  In step S186, the arithmetic operation circuit 101 determines whether or not the sensitivity setting switch SW4 is turned off. If the off signal is input from the sensitivity setting switch SW4, the arithmetic operation circuit 101 makes an affirmative decision in step S186, ends the process of FIG. 15, and proceeds to step S6 of FIG. If the off signal is not input from the sensitivity setting switch SW4, the arithmetic operation circuit 101 makes a negative determination in step S186 and returns to step S172.

  In step S191 of FIG. 16 which proceeds after making a negative determination in step S171 described above, the arithmetic operation circuit 101 determines whether or not the sensitivity automatic change mode setting is changed. The arithmetic operation circuit 101 makes an affirmative decision in step S191 when an operation signal is input from the automatic sensitivity change mode setting operation member 112 and proceeds to step S192. If an operation signal is not input, the operation circuit 101 makes a negative determination in step S191. Proceed to S195.

  In step S192, the arithmetic operation circuit 101 makes a decision as to whether or not the sensitivity automatic change mode flag S = 0. The arithmetic operation circuit 101 makes an affirmative decision in step S192 when S = 0 (cancels automatic sensitivity change mode) and proceeds to step S193, and negates step S192 when S = 1 (sets the automatic sensitivity change mode). Determination is made and the process proceeds to step S194.

  In step S193, the arithmetic operation circuit 101 sets the flag S to 1 to end the processing in FIG. 16, and proceeds to step S6 in FIG. In step S194, the arithmetic operation circuit 101 sets the flag S to 0, ends the processing of FIG. 16, and proceeds to step S6 of FIG.

  In step S195, which proceeds after making a negative determination in step S191, the arithmetic operation circuit 101 determines whether or not the exposure mode switch SW3 is turned on. The arithmetic operation circuit 101 makes an affirmative decision in step S195 when an on signal is input from the exposure mode switch SW3, and proceeds to step S196. If an on signal is not input from the exposure mode switch SW3, the arithmetic circuit 101 denies step S195. Determination is made, and the process proceeds to step S211 in FIG.

  In step S196, the arithmetic operation circuit 101 determines whether or not the main command dial 110 has been rotated counterclockwise. The arithmetic operation circuit 101 makes an affirmative decision in step S196 when an operation signal indicating counterclockwise rotation is input from the main command dial 110, and proceeds to step S197. If an operation signal indicating counterclockwise rotation is not input, the arithmetic operation circuit 101 proceeds to step S196. Is negatively determined, and the process proceeds to step S200.

  In step S197, the arithmetic operation circuit 101 makes a decision as to whether or not the exposure mode parameter M = 4. The arithmetic operation circuit 101 makes an affirmative decision in step S197 when M = 4 (manual exposure mode) and proceeds to step S199. If M ≠ 4, the operation circuit 101 makes a negative decision in step S197 and proceeds to step S198. In step S198, the arithmetic operation circuit 101 adds 1 to the value of M and proceeds to step S204. In step S199, the arithmetic operation circuit 101 sets 1 to the value of M, and then proceeds to step S204. As a result, the exposure mode is cyclically changed from P → S → A → M → P.

  In step S200, the arithmetic operation circuit 101 determines whether or not the main command dial 110 has been rotated clockwise. The arithmetic operation circuit 101 makes an affirmative decision in step S200 when an operation signal indicating clockwise rotation is input from the main command dial 110, and proceeds to step S201. If an operation signal indicating clockwise rotation is not input, the arithmetic circuit 101 negates step S200. Determine and proceed to step S204.

  In step S201, the arithmetic circuit 101 determines whether or not the exposure mode parameter M = 1. The arithmetic operation circuit 101 makes an affirmative decision in step S201 when M = 1 (programmed auto exposure operation mode) and proceeds to step S203. If M ≠ 1, the operation circuit 101 makes a negative determination in step S201 and proceeds to step S202. In step S202, the arithmetic operation circuit 101 subtracts 1 from the value of M and proceeds to step S204. In step S203, the arithmetic operation circuit 101 sets 4 as the value of M, and then proceeds to step S204. As a result, the exposure mode is cyclically changed from M → A → S → P → M.

  In step S204, the arithmetic operation circuit 101 sends a command to each of the in-finder display device 1091 and the external display device 1092 so that the set exposure mode is lit and proceeds to step S205. Each of the in-viewfinder display device 1091 and the external display device 1092 lights a character or mark (for example, “P”, “S”, “A”, “M”) corresponding to the set exposure mode. indicate.

  In step S205, the arithmetic circuit 101 determines whether or not the exposure mode switch SW3 is turned off. The arithmetic operation circuit 101 makes an affirmative decision in step S205 when an off signal is input from the exposure mode switch SW3, ends the process of FIG. 16, and proceeds to step S6 of FIG. If the OFF signal is not input from the exposure mode switch SW3, the arithmetic operation circuit 101 makes a negative determination in step S205 and returns to step S196.

  In step S211 of FIG. 17 which proceeds after making a negative determination in step S195 described above, the arithmetic operation circuit 101 determines whether or not the exposure mode parameter M = 2. If M = 2 (shutter speed priority exposure calculation mode), the arithmetic operation circuit 101 makes an affirmative decision in step S211 and proceeds to step S213. If M ≠ 2, the operation circuit 101 makes a negative determination in step S211 and proceeds to step S212.

  In step S212, the arithmetic circuit 101 determines whether or not the exposure mode parameter M = 4. The arithmetic operation circuit 101 makes an affirmative decision in step S212 when M = 4 (manual exposure mode) and proceeds to step S213. If M ≠ 4, the operation circuit 101 makes a negative decision in step S212 and proceeds to step S219.

  In step S213, the arithmetic operation circuit 101 determines whether or not the main command dial 110 has been rotated counterclockwise. The arithmetic operation circuit 101 makes an affirmative decision in step S213 when an operation signal indicating counterclockwise rotation is input from the main command dial 110, and proceeds to step S214. If an operation signal indicating counterclockwise rotation is not input, the arithmetic operation circuit 101 proceeds to step S213. Is negatively determined, and the process proceeds to step S216.

  In step S214, the arithmetic operation circuit 101 makes a decision as to whether TVs = 10. The arithmetic operation circuit 101 makes an affirmative decision in step S214 when TVs = 10 (set shutter speed is 1/1000 second), terminates the process in FIG. 17, and proceeds to step S6 in FIG. In this case, since the upper limit of the shutter speed setting range, the setting process is terminated without increasing the speed. On the other hand, the arithmetic operation circuit 101 makes a negative determination in step S214 when TVs ≠ 10, and proceeds to step S215. In step S215, the arithmetic operation circuit 101 adds 1 to the set shutter speed TVs, ends the processing in FIG. 17, and proceeds to step S6 in FIG. As a result, the set shutter speed TVs is increased by one step.

  In step S216, the arithmetic operation circuit 101 determines whether or not the main command dial 110 has been rotated clockwise. The arithmetic operation circuit 101 makes an affirmative decision in step S216 when an operation signal indicating clockwise rotation is input from the main command dial 110 and proceeds to step S217. If an operation signal indicating clockwise rotation is not input, the arithmetic circuit 101 negates step S216. Determination is made and the process proceeds to step S219.

  In step S217, the arithmetic circuit 101 determines whether TVs = 0. The arithmetic operation circuit 101 makes an affirmative decision in step S217 when TVs = 0 (set shutter speed is 1 second), terminates the processing in FIG. 17, and proceeds to step S6 in FIG. In this case, since the lower limit of the shutter speed setting range, the setting process is terminated without reducing the speed. On the other hand, if TVs ≠ 0, the arithmetic operation circuit 101 makes a negative determination in step S217 and proceeds to step S218. In step S218, the arithmetic operation circuit 101 subtracts 1 from the set shutter speed TVs, ends the processing of FIG. 17, and proceeds to step S6 of FIG. As a result, the set shutter speed TVs is reduced by one step.

  In step S219, the arithmetic operation circuit 101 makes a decision as to whether or not the exposure mode parameter M = 3. The arithmetic operation circuit 101 makes an affirmative decision in step S219 when M = 3 (aperture value priority exposure operation mode) and proceeds to step S221. If M ≠ 3, the operation circuit 101 makes a negative determination in step S219 and proceeds to step S220.

  In step S220, the arithmetic operation circuit 101 makes a decision as to whether or not the exposure mode parameter M = 4. The arithmetic operation circuit 101 makes an affirmative decision in step S220 when M = 4 (manual exposure mode) and proceeds to step S221. If M ≠ 4, the operation circuit 101 makes a negative decision in step S220, and ends the processing of FIG. Proceed to step S6 in FIG.

  In step S221, the arithmetic operation circuit 101 determines whether or not the subcommand dial 111 has been rotated clockwise. The arithmetic operation circuit 101 makes an affirmative decision in step S221 when an operation signal indicating clockwise rotation is input from the subcommand dial 111, and proceeds to step S222. If an operation signal indicating clockwise rotation is not input, the arithmetic circuit 101 negates step S221. Determination is made and the process proceeds to step S224.

  In step S222, the arithmetic operation circuit 101 makes a decision as to whether AVs = 9. The arithmetic operation circuit 101 makes an affirmative decision in step S222 when AVs = 9 (the set aperture value is F22), terminates the processing in FIG. 17, and proceeds to step S6 in FIG. In this case, the setting process is terminated because it is the upper limit of the aperture value setting range. If AVs ≠ 9, the arithmetic operation circuit 101 makes a negative determination in step S222 and proceeds to step S223.

  In step S223, the arithmetic operation circuit 101 adds 1 to the set aperture value AVs, ends the processing in FIG. 17, and proceeds to step S6 in FIG. As a result, the aperture diameter is decreased by one aperture (the set aperture value AVs is increased by one step).

  In step S224, the arithmetic operation circuit 101 makes a decision as to whether or not the subcommand dial 111 has been rotated counterclockwise. The arithmetic operation circuit 101 makes an affirmative decision in step S224 when an operation signal indicating counterclockwise rotation is input from the subcommand dial 111, and proceeds to step S225. If an operation signal indicating counterclockwise rotation is not input, the arithmetic circuit 101 proceeds to step S224. Is negatively determined, the processing in FIG. 17 is terminated, and the process proceeds to step S6 in FIG.

  In step S225, the arithmetic operation circuit 101 makes a decision as to whether AVs = 3. When AVs = 3 (the set aperture value is F2.8), the arithmetic operation circuit 101 makes an affirmative decision in step S225, ends the process of FIG. 17, and proceeds to step S6 of FIG. In this case, since it is the lower limit of the aperture value setting range, the setting process is terminated. If AVs ≠ 3, the arithmetic operation circuit 101 makes a negative determination in step S225 and proceeds to step S226.

  In step S226, the arithmetic operation circuit 101 subtracts 1 from the set aperture value AVs, ends the processing of FIG. 17, and proceeds to step S6 of FIG. As a result, the aperture diameter increases by one aperture (set aperture value AVs is decreased by one step).

(Release sequence processing)
Details of the release sequence process will be described with reference to the flowchart of FIG. In step S231 in FIG. 22, the arithmetic circuit 101 outputs a command to the shutter control circuit 103, and energizes a magnet (not shown) of the shutter 104 to hold the front curtain and the rear curtain. In step S232, the arithmetic circuit 101 outputs a command to the motor control circuit 105, causes the sequence motor 106 to start normal rotation, and proceeds to step S233. As a result, the mirror up and the aperture stop of the mirror (not shown) are started. In step S233, the arithmetic operation circuit 101 detects the drive aperture value AVk based on the signal input from the aperture position detection device 107, and proceeds to step S234.

  In step S234, the arithmetic operation circuit 101 makes a decision as to whether AVk ≧ AVc is established between the drive aperture value AVk and the control aperture value AVc. The arithmetic operation circuit 101 makes an affirmative decision in step S234 when AVk ≧ AVc is established and proceeds to step S235, and makes a negative decision in step S234 if AVk ≧ AVc is not established. If a negative determination is made, the process returns to step S233 so as to continue the narrowing down.

  In step S235, the arithmetic operation circuit 101 outputs a command to the aperture locking device 108, locks the aperture, and proceeds to step S236. In step S236, the arithmetic operation circuit 101 determines whether or not the mirror up has been completed. The arithmetic operation circuit 101 makes an affirmative decision in step S236 when an ON signal is input from the sequence switch SW1, and proceeds to step S237. If an ON signal is not input from the sequence switch SW1, the arithmetic circuit 101 makes a negative determination in step S236. If a negative determination is made, the determination process is repeated so as to continue the mirror up.

  In step S237, the arithmetic circuit 101 outputs a command to the motor control circuit 105, stops the sequence motor 106, and proceeds to step S238. Note that a sequence driving device (not shown) is configured so that the stop of the stop is ended by the stop locking device 108 before the end of the mirror up. In step S238, the arithmetic operation circuit 101 causes the timing circuit 124 to start generating a drive signal to start driving the image sensor 121, and proceeds to step S239. As a result, the image sensor 121 starts charge accumulation.

In step S239, the arithmetic circuit 101 waits for a predetermined time (at least until the bounce at the time of mirror up is stabilized), and proceeds to step S240. In step S240, the arithmetic operation circuit 101 outputs a command to the shutter control circuit 103, cancels energization of the magnet (not shown) of the shutter 104 to release the front curtain holding, and proceeds to step S241. As a result, traveling of the shutter front curtain is started, and the image sensor 121 accumulates electric charges according to the intensity of the subject light that has reached the imaging surface of the image sensor 121. In step S241, the arithmetic operation circuit 101 implements a weight for a time (= 2 ^−TVc ) corresponding to the control shutter speed TVc, and then proceeds to step S242.

  In step S242, the arithmetic operation circuit 101 outputs a command to the shutter control circuit 103, cancels energization of the magnet (not shown) of the shutter 104 to release the rear curtain holding, and proceeds to step S243. Thereby, the running of the shutter rear curtain is started, and the subject light to the image sensor 121 is blocked.

  In step S243, the arithmetic operation circuit 101 executes a shutter rear curtain travel completion weight, and then proceeds to step S244. The wait time is the time required for the trailing curtain to completely shield the image pickup area of the image pickup device 121 and complete the running. In step S244, the arithmetic operation circuit 101 ends the charge accumulation of the image sensor 121 and proceeds to step S245. In step S245, the arithmetic circuit 101 outputs a command to the motor control circuit 105, causes the sequence motor 106 to start reverse rotation, and proceeds to step S246. Thereby, the mirror down of the mirror (not shown) and the return of the aperture to the open state are started. In step S246, the arithmetic operation circuit 101 outputs a command to the timing circuit 124 to read out the accumulated charge from the image sensor 121, and the process proceeds to step S247.

  In step S247, the arithmetic operation circuit 101 causes the ASIC 123 to perform image processing, and proceeds to step S248. In step S248, the arithmetic operation circuit 101 causes the ASIC 123 to perform image compression processing, and proceeds to step S249. In step S249, the arithmetic operation circuit 101 records the image data stored in the buffer memory 125 after the image compression on the recording medium 126, and proceeds to step S250.

  In step S250, the arithmetic operation circuit 101 makes a decision as to whether or not mirror down has been completed. When the ON signal is input from the sequence switch SW1, the arithmetic operation circuit 101 makes an affirmative determination in step S250 and proceeds to step S251. When the ON signal is not input from the sequence switch SW1, the arithmetic circuit 101 makes a negative determination in step S250 and continues mirror down. Repeat the determination process.

  In step S251, the arithmetic operation circuit 101 outputs a command to the motor control circuit 105, stops the sequence motor 106, ends the processing in FIG. 22, and returns to step S2 in FIG. As a result, a series of photographing processes is completed.

According to the embodiment described above, the following effects can be obtained.
(1) When the sensitivity setting switch SW4 is turned on, the electronic camera displays the control imaging sensitivity SVc after the exposure calculation on the in-finder display device 1091 (FIGS. 19, 20, and 21). Normally, the display sensitivity is displayed by a display segment that performs another display (display of the shutter speed in the present embodiment), so that the imaging sensitivity can be displayed without providing a new display segment. Furthermore, since other displays (aperture value, etc.) different from the imaging sensitivity are not displayed, the display contents are easy to understand.

(2) In the electronic camera, after the display of the above (1) is started, the imaging sensitivity is automatically changed by the exposure calculation processing in the imaging sensitivity automatic change mode (S = 1) (a value different from the set imaging sensitivity SVs is controlled imaging). When the sensitivity is set to SVc), the display segment “ISO Auto” 94A is displayed blinking on the in-finder display device 1091 and the display segment 191A indicating the imaging sensitivity after being automatically changed (control imaging sensitivity SVc) is lit on ( FIG. 19). It can be shown that the imaging sensitivity has been automatically changed by blinking of the display segment “ISO Auto” 94A, and the imaging sensitivity after the automatic change (control imaging sensitivity SVc) can be shown by turning on the display segment 191A.

(3) The electronic camera, when the imaging sensitivity is not automatically changed by the exposure calculation process in the imaging sensitivity automatic change mode (S = 1) after the start of the display of (1) above (the set imaging sensitivity SVs becomes the control imaging sensitivity SVc) Is set), the display segment “ISO Auto” 94 is lit on the in-finder display device 1091 and the display segment 191 indicating the control imaging sensitivity SVc is lit (FIG. 20). Illumination of the display segment “ISO Auto” 94 indicates that the imaging sensitivity is not automatically changed, and illumination of the display segment 191 can indicate the set imaging sensitivity SVs before automatic change (before exposure calculation).

(4) In the electronic camera, when the imaging sensitivity automatic change mode is canceled (S = 0) after the display of the above (1) is started (the set imaging sensitivity SVs is set to the control imaging sensitivity SVc by the exposure calculation process). Displays a display segment 191 indicating the control imaging sensitivity SVc on the in-finder display device 1091 (FIG. 21). It can be shown that the imaging sensitivity automatic change mode has been canceled by non-lighting of the display segment “ISO Auto”, and the set imaging sensitivity SVs can be shown by lighting of the display segment 191.

(5) When the sensitivity setting switch SW4 is turned on, the electronic camera displays the set imaging sensitivity SVs on the external display device 1092 (FIG. 18). Normally, the display sensitivity is displayed by a display segment that performs another display (display of the shutter speed in the present embodiment), so that the imaging sensitivity can be displayed without providing a new display segment. Further, since other displays (aperture value, etc.) different from the imaging sensitivity are not displayed, the display contents are easy to understand. Further, a display segment indicating the set imaging sensitivity SVs before the automatic change (before the exposure calculation) regardless of whether or not the imaging sensitivity is automatically changed by the exposure calculation process in the imaging sensitivity automatic change mode (S = 1). Since 182 is lit up, the set imaging sensitivity SVs during the setting operation can be displayed on the external display device 1092 while the control imaging sensitivity SVc is displayed on the display device 1091 in the viewfinder.

(Modification)
You may comprise so that an electronic camera may be equipped with the operation member for displaying imaging sensitivity on the display apparatus 1091 in a finder or the external display apparatus 1092. FIG. 23 is a block diagram illustrating a configuration of an electronic camera according to a modification. In addition to the configuration of FIG. 1, a custom setting operation member 201 and a function switch SW5 are provided.

  The custom setting operation member 201 generates an operation signal for changing the setting of the custom setting and sends it to the arithmetic circuit 101 ′. The arithmetic circuit 101 ′ according to the present embodiment switches whether the function switch SW5 is handled as an imaging sensitivity display instruction switch each time an operation signal from the custom setting operation member 201 is input.

  The function switch SW5 is turned on in conjunction with a pressing operation of a function button (not shown) and outputs an on signal to the arithmetic circuit 101 ′, while being turned off in conjunction with the release of the function button, the off signal is supplied to the arithmetic circuit 101 ′. Output to.

(Main processing in the modification)
A flow of camera operation processing performed by the arithmetic circuit 101 ′ of the electronic camera according to the modification will be described with reference to a flowchart of FIG. The program according to the flowchart of FIG. 24 starts when a battery (not shown) is loaded in the electronic camera. In FIG. 24, the processing in step S11A and steps S14 to S16 is different from that in FIG. 4, so these differences will be mainly described and description of the processing overlapping with that in FIG. 4 will be omitted.

  In step S11A of FIG. 24, the arithmetic circuit 101 ′ performs the following initial settings. That is, the set imaging sensitivity SVs is set to 7 (corresponding to ISO 400), the set shutter speed TVs is set to 7 (1/125 seconds), the set aperture value AVs is set to 5 (F5.6), the mode parameter M is set to 1, and the sensitivity is set. The automatic change mode flag S is set to 0, the custom setting flag F is set to 0, and the process proceeds to step S2. The custom setting flag F is set to 1 when the function switch SW5 is handled as an imaging sensitivity display instruction switch (custom setting is set), and when the function switch SW5 is not used as an imaging sensitivity display instruction switch (custom setting is canceled). This flag is set to 0.

  In step S14, the arithmetic circuit 101 ′ performs the display A process and proceeds to step S15. Details of the display A process will be described later. In step S15, the arithmetic operation circuit 101 ′ performs the setting A process and proceeds to step S16. Details of the setting A process will be described later. In step S16, the arithmetic operation circuit 101 ′ performs the display A process again and proceeds to step S7.

(Display processing in modification)
Details of the display A process will be described with reference to the flowchart of FIG. In step S301 in FIG. 25, the arithmetic circuit 101 ′ sends commands to the display device 1091 in the viewfinder and the external display device 1092, and the set exposure mode, control shutter speed TVc, and control aperture value AVc are lit up. Then, the process proceeds to step S302. The in-finder display device 1091 and the external display device 1092 display as illustrated in FIGS. 9 and 10, respectively.

  In step S302, the arithmetic operation circuit 101 ′ determines whether or not the custom setting flag F = 1. The arithmetic operation circuit 101 ′ makes an affirmative decision in step S302 when F = 1 (custom setting is set) and proceeds to step S303, and makes a negative decision in step S302 if F = 0 (custom setting is canceled). Then, the process proceeds to step S304.

  In step S303, the arithmetic operation circuit 101 ′ sends a command to the external display device 1092 to turn on the display segment “CSM” indicating that the custom setting has been set, and then the operation proceeds to step S304.

  The processing from step S304 to step S307 is the same as the processing from step S162 to step S165 in FIG. After the process of FIG. 25 is completed, if the setting A process (step S15) is not completed in FIG. 24, the process proceeds to step S15. If the setting A process (step S15) is completed, the process proceeds to step S7.

(Setting process in the modification)
Details of the setting A process will be described with reference to the flowcharts of FIGS. In step S401 of FIG. 26, the arithmetic circuit 101 ′ determines whether or not the custom setting flag F = 1. The arithmetic operation circuit 101 ′ makes an affirmative decision in step S401 when F = 1 (custom setting is set), and proceeds to step S402. If F = 0 (cancel custom setting), the operation circuit 101 ′ makes a negative decision in step S401. Then, the process proceeds to step S421 in FIG.

  In step S402, the arithmetic operation circuit 101 ′ determines whether or not the function switch SW5 is turned on. The arithmetic operation circuit 101 ′ makes an affirmative determination in step S402 when an on signal is input from the function switch SW5, and proceeds to step S403. If the on signal is not input from the function switch SW5, the arithmetic circuit 101 ′ makes a negative determination in step S402. Then, the process proceeds to step S421 in FIG.

  The processing in step S403 and step S404 is the same as the processing in step S178 and step S179 in FIG.

  Further, the processing from step S405 to step S409 is the same as the processing from step S181 to step S185 in FIG.

  In step S410, the arithmetic operation circuit 101 ′ determines whether or not the function switch SW5 is turned off. If the OFF signal is input from the function switch SW5, the arithmetic operation circuit 101 ′ makes an affirmative decision in step S410, ends the process in FIG. 26, and proceeds to step S16 in FIG. If the off signal is not input from the function switch SW5, the arithmetic operation circuit 101 ′ makes a negative determination in step S410 and returns to step S403.

  In step S421 in FIG. 27, the arithmetic operation circuit 101 ′ determines whether or not the custom setting has been changed. The arithmetic circuit 101 ′ makes an affirmative decision in step S421 when an operation signal is input from the custom setting operation member 201, and proceeds to step S422. If an operation signal is not input from the custom setting operation member 201, the arithmetic circuit 101 ′ performs step S421. A negative determination is made and processing proceeds to step S425.

  In step S422, the arithmetic operation circuit 101 ′ determines whether or not the custom setting flag F = 0. The arithmetic operation circuit 101 ′ makes an affirmative decision in step S422 when F = 0 (custom setting is canceled), and proceeds to step S423. If F = 1 (custom setting is set), the arithmetic circuit 101 ′ proceeds to step S422. Is negatively determined, and the process proceeds to step S424.

  In step S423, the arithmetic circuit 101 ′ sets the flag F to 1 (sets a custom setting), ends the process of FIG. 27, and proceeds to step S16 of FIG. In step S424, the arithmetic operation circuit 101 ′ sets the flag F to 0 (cancels the custom setting), ends the processing of FIG. 27, and proceeds to step S16 of FIG.

  In step S425, the arithmetic operation circuit 101 ′ determines whether or not the sensitivity setting switch SW4 is turned on. The arithmetic operation circuit 101 ′ makes an affirmative decision in step S425 when an on signal is input from the sensitivity setting switch SW4, and proceeds to step S426. If an on signal is not input from the sensitivity setting switch SW4, the arithmetic operation circuit 101 ′ performs step S425. A negative determination is made, and the process proceeds to step S191 in FIG.

  In step S426, the arithmetic operation circuit 101 ′ determines whether or not the main command dial 110 has been rotated counterclockwise. The arithmetic circuit 101 ′ makes an affirmative decision in step S426 when an operation signal indicating counterclockwise rotation is input from the main command dial 110, and proceeds to step S427. If an operation signal indicating counterclockwise rotation is not input, the arithmetic circuit 101 ′ performs step. A negative determination is made in S426, and the process proceeds to Step S429.

  In step S427, the arithmetic circuit 101 ′ determines whether SVs = 9. If SVs = 9 (the set imaging sensitivity is equivalent to ISO 1600), the arithmetic operation circuit 101 ′ makes an affirmative decision in step S427 and proceeds to step S432. In this case, since the upper limit of the imaging sensitivity setting range, the sensitivity is not further increased. On the other hand, when SVs ≠ 9, the arithmetic operation circuit 101 ′ makes a negative determination in step S427 and proceeds to step S428. In step S428, the arithmetic operation circuit 101 ′ adds 1 to the set imaging sensitivity SVs and proceeds to step S432. As a result, the set imaging sensitivity SVs is changed by one step.

  In step S429, the arithmetic circuit 101 ′ determines whether or not the main command dial 110 has been rotated clockwise. The arithmetic circuit 101 ′ makes an affirmative decision in step S429 when an operation signal indicating clockwise rotation is input from the main command dial 110, and proceeds to step S430. If an operation signal indicating clockwise rotation is not input, the arithmetic circuit 101 ′ performs step S429. A negative determination is made and processing proceeds to step S432.

  In step S430, the arithmetic circuit 101 ′ determines whether SVs = 5. If SVs = 5 (the set imaging sensitivity is equivalent to ISO 100), the arithmetic operation circuit 101 ′ makes an affirmative determination in step S430 and proceeds to step S432. In this case, since the lower limit of the imaging sensitivity setting range, the sensitivity is not further reduced. On the other hand, when SVs ≠ 5, the arithmetic operation circuit 101 ′ makes a negative determination in step S430 and proceeds to step S431. In step S431, the arithmetic operation circuit 101 ′ subtracts 1 from the set imaging sensitivity SVs and proceeds to step S432. As a result, the set imaging sensitivity SVs is changed by one step.

  In step S432, the arithmetic operation circuit 101 ′ sends a command to the external display device 1092 so that the characters or marks “ISO” and the set imaging sensitivity SVs are lit up and the process proceeds to step S433. The external display device 1092 displays “ISO” and the imaging sensitivity corresponding to the apex value (FIG. 18).

  In step S433, the arithmetic circuit 101 ′ determines whether or not the sensitivity setting switch SW4 is turned off. If the off signal is input from the sensitivity setting switch SW4, the arithmetic operation circuit 101 ′ makes an affirmative decision in step S433, ends the process of FIG. 27, and proceeds to step S16 of FIG. If the off signal is not input from the sensitivity setting switch SW4, the arithmetic operation circuit 101 ′ makes a negative determination in step S433 and returns to step S426.

According to the modification described above, the following operational effects can be obtained.
(1) When the function switch SW5 is turned on while the custom setting is set, the electronic camera displays the control imaging sensitivity SVc after the exposure calculation on the in-finder display device 1091 (FIGS. 19, 20, and FIG. 21). Normally, the display sensitivity is displayed by a display segment that performs another display (display of the shutter speed in the present embodiment), so that the imaging sensitivity can be displayed without providing a new display segment. Furthermore, since other displays (aperture value, etc.) different from the imaging sensitivity are not displayed, the display contents are easy to understand.

(2) In the electronic camera, after the display of (1) above is started, the imaging sensitivity is automatically changed by the exposure calculation processing in the imaging sensitivity automatic change mode (S = 1) (a value different from the set imaging sensitivity SVs is controlled imaging) When the sensitivity is set to SVc), the display segment “ISO Auto” 94A is displayed blinking on the display device 1091 in the viewfinder, and the display segment 191A indicating the imaging sensitivity after being automatically changed (control imaging sensitivity SVc) is lit and displayed ( FIG. 19). It can be shown that the imaging sensitivity has been automatically changed by blinking of the display segment “ISO Auto” 94A, and the imaging sensitivity after the automatic change (control imaging sensitivity SVc) can be shown by turning on the display segment 191A.

(3) The electronic camera, when the imaging sensitivity is not automatically changed by the exposure calculation process in the imaging sensitivity automatic change mode (S = 1) after the start of the display of (1) above (the set imaging sensitivity SVs becomes the control imaging sensitivity SVc) Is set), the display segment “ISO Auto” 94 is lit on the in-finder display device 1091 and the display segment 191 indicating the control imaging sensitivity SVc is lit (FIG. 20). Illumination of the display segment “ISO Auto” 94 indicates that the imaging sensitivity is not automatically changed, and illumination of the display segment 191 can indicate the set imaging sensitivity SVs before automatic change (before exposure calculation).

(4) In the electronic camera, when the imaging sensitivity automatic change mode is canceled (S = 0) after the display of the above (1) is started (the set imaging sensitivity SVs is set to the control imaging sensitivity SVc by the exposure calculation process). Displays a display segment 191 indicating the control imaging sensitivity SVc on the in-finder display device 1091 (FIG. 21). It can be shown that the imaging sensitivity automatic change mode has been canceled by non-lighting of the display segment “ISO Auto”, and the set imaging sensitivity SVs can be shown by lighting of the display segment 191.

(5) When the sensitivity setting switch SW4 is turned on, the electronic camera displays the set imaging sensitivity SVs on the external display device 1092 (FIG. 18). Normally, the display sensitivity is displayed by a display segment that performs another display (display of the shutter speed in the present embodiment), so that the imaging sensitivity can be displayed without providing a new display segment. Further, since other displays (aperture value, etc.) different from the imaging sensitivity are not displayed, the display contents are easy to understand. Further, a display segment indicating the set imaging sensitivity SVs before the automatic change (before the exposure calculation) regardless of whether or not the imaging sensitivity is automatically changed by the exposure calculation process in the imaging sensitivity automatic change mode (S = 1). Since 182 is lit up, the set imaging sensitivity SVs during the setting operation can be displayed on the external display device 1092 while the control imaging sensitivity SVc is displayed on the display device 1091 in the viewfinder.

  The imaging sensitivity range (equivalent to ISO100 to ISO1600), shutter speed range (1 second to 1/1000 second), and aperture value range (F2.8 to F22) in the electronic camera described above are examples. You may comprise so that control is possible in ranges other than.

  In the electronic camera described above, the control imaging sensitivity SVc is displayed on the in-finder display device 1091 in response to the ON operation of the operation member (sensitivity setting switch SW4 or function switch SW5) for displaying the imaging sensitivity (FIG. 19, 20 and 21), in response to the turning-off operation of the operation member (sensitivity setting switch SW4 or function switch SW5) for displaying the imaging sensitivity, the display of the control imaging sensitivity SVc by the in-finder display device 1091 is terminated. did. Instead of this, the display of the control imaging sensitivity SVc by the display device 1091 in the viewfinder may be automatically ended when a predetermined time (for example, 1 second) elapses from the display start of the control imaging sensitivity SVc.

  Although the example in which the electronic camera is provided with the in-finder display device 1091 and the external display device 1092 has been described, the present invention may be applied to an electronic camera provided with an external display monitor and the external display device 1092. In this case, the control imaging sensitivity SVc is displayed on the external display monitor in accordance with the ON operation of the operation member for displaying the imaging sensitivity.

It is a block diagram which shows the structure of the electronic camera by one Embodiment of this invention. It is a figure which illustrates the display segment of the display apparatus in a finder. It is a figure which illustrates the display segment of an external display device. It is a flowchart explaining the flow of a process of camera operation | movement. It is a flowchart explaining the detail of an exposure calculation process. It is a flowchart explaining the detail of an exposure calculation process. It is a flowchart explaining the detail of an exposure calculation process. It is a flowchart explaining the detail of a display process. It is a figure which illustrates the display content by the display apparatus in a finder. It is a figure which illustrates the display contents by an external display device. It is a figure which illustrates the display content by the display apparatus in a finder. It is a figure which illustrates the display contents by an external display device. It is a figure which illustrates the display content by the display apparatus in a finder. It is a figure which illustrates the display contents by an external display device. It is a flowchart explaining the detail of a setting process. It is a flowchart explaining the detail of a setting process. It is a flowchart explaining the detail of a setting process. It is a figure which illustrates the display contents by an external display device. It is a figure which illustrates the display content by the display apparatus in a finder. It is a figure which illustrates the display content by the display apparatus in a finder. It is a figure which illustrates the display content by the display apparatus in a finder. It is a flowchart explaining the detail of a release sequence process. It is a block diagram which shows the structure of the electronic camera by a modification. It is a flowchart explaining the flow of a process of camera operation | movement. It is a flowchart explaining the detail of a display A process. It is a flowchart explaining the detail of a setting A process. It is a flowchart explaining the detail of a setting A process.

Explanation of symbols

101 (101 ') ... arithmetic circuit 110 ... main command dial 111 ... subcommand dial 112 ... sensitivity automatic change mode setting operation member 121 ... imaging element 201 ... custom setting setting operation member 1091 ... in-finder display device 1092 ... external display device SW3 ... Exposure mode switch SW4 ... Sensitivity setting switch SW5 ... Function switch

Claims (3)

An imaging device for imaging a subject image;
The exposure calculation is performed using the exposure sensitivity set in the imaging apparatus, and the control exposure is changed by changing the set exposure sensitivity so that it approaches the appropriate exposure when the appropriate exposure cannot be obtained by the exposure calculation. Exposure calculation means for calculating;
An electronic camera comprising: display means for performing display indicating the changed exposure sensitivity in response to the exposure calculation means changing the exposure sensitivity. An imaging device for imaging a subject image;
An exposure sensitivity display operation member that outputs an operation signal for displaying the exposure sensitivity of the imaging device;
The exposure calculation is performed using the exposure sensitivity set in the imaging apparatus, and the control exposure is changed by changing the set exposure sensitivity so that it approaches the appropriate exposure when the appropriate exposure cannot be obtained by the exposure calculation. Exposure calculation means for calculating;
An electronic camera comprising: display means for performing display indicating exposure sensitivity after calculation by the exposure calculation means in response to the operation signal being output from the exposure sensitivity display operation member. The electronic camera according to claim 1 or 2,
The display means is an internal display device provided in a finder,
An exposure sensitivity setting operation member that outputs an operation signal for setting the exposure sensitivity of the imaging device;
An external display device that is provided in a camera casing and that performs display indicating the exposure sensitivity set by the operation signal in response to the operation signal being output from the exposure sensitivity setting operation member. An electronic camera characterized by

Images