JP4612518B2 - Electron multiplication type imaging apparatus and sensitivity adjustment method thereof - Google Patents

Description

  The present invention relates to a television camera, and more particularly to automatic sensitivity adjustment when a lens capable of aperture control and an electron multiplying solid-state imaging device are combined.

Conventionally, in order to maintain high image quality in a television camera that combines a lens that can control the aperture and an imaging tube that can adjust sensitivity, the transmittance of the ND filter is first changed, and then automatic sensitivity adjustment is performed using the gain of the video signal processing system. An example in which automatic sensitivity adjustment is performed by switching to a state in which the aperture of the lens is opened when it becomes impossible to follow is disclosed.
JP 2004-289348 A

In the prior art, automatic sensitivity adjustment with the lens aperture opened (fully open) may not always maintain high image quality because the subject may be out of focus due to lens characteristics.
An object of the present invention is to perform an automatic sensitivity adjustment with an optimum image quality priority.

  In order to achieve the above object, a sensitivity adjustment method for a television camera according to the present invention includes a lens unit capable of aperture control, and an image obtained by imaging incident light from the lens unit with an electron multiplier type imaging device and outputting a video signal. In a camera, a predetermined range of the lens unit diaphragm is controlled to open and close, and outside the predetermined range of the lens unit diaphragm, the lens unit diaphragm is maintained within the predetermined open / close range and the electron multiplication factor of the electron multiplying image sensor is controlled. To do.

  The television camera sensitivity adjusting apparatus according to the present invention includes a lens unit capable of aperture control and a television camera that captures incident light from the lens unit with an electron multiplying image sensor and outputs a video signal. The aperture opening / closing control means, the electron multiplication factor control means of the electron multiplier type imaging device, and the control means for adaptively controlling the opening / closing control means and the electron multiplication factor control means.

  According to the present invention, in the automatic sensitivity adjustment when the lens capable of controlling the aperture and the electron multiplying solid-state imaging device are combined, the automatic sensitivity adjustment with the optimum image quality priority can be performed.

An embodiment of a television camera according to the present invention will be described below with reference to FIGS.
FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention. FIG. 1 shows only the portions necessary for the description of the television camera of the present invention.

  In FIG. 1, 1 is a lens unit that can control the aperture, 2 is an aperture control unit that controls the aperture mechanism of the lens unit 1, and 3 is an imaging unit that photoelectrically converts incident light from the lens unit 1 and outputs a video signal. is there. 4 is an EM-CCD (Electron Multiplying-Charge Coupled Device) that converts light incident from the lens unit 1 into an electrical signal, and 5 is an adaptive gain for the signal output from the EM-CCD 4. AGC (Automatic Gain Control) to be adjusted to 6, 6 is a video processing unit that performs various image processing on the signal output from AGC 5, 7 is NTSC (National Television System Committee) method, PAL (Phase Alternating by Line) method, etc. ENC (Encoder) for converting a video signal, 8 is a combining unit that combines a signal output from ENC 7 and a signal output from character signal generation unit 14 (described later), and 30 is a signal output from combining unit 8. 9 is a drive unit for driving the EM-CCD 4 and controlling gain of electron multiplication, and 13 is a video process according to a program predetermined according to the input signal. 6 and a CPU (Central Processing Unit) 14 for controlling each part in the image pickup unit 3 such as a character signal generator 14 (described later), 14 generates a character signal for displaying characters on the monitor 30 in accordance with a signal output from the CPU 13. It is a character signal generator. A lens aperture control unit 12 generates a signal b and a signal c for controlling the aperture of the lens unit 1 in accordance with the signal a input from the video processing unit 6 and outputs a signal f of the lens aperture ratio. It is. Reference numeral 11 denotes an amplifier that amplifies the signal c input from the lens aperture controller 12, and 10 denotes the presence or absence of the amplifier of the lens unit 1 (hereinafter, the lens unit 1 incorporating the amplifier is referred to as a VIDEO lens. A switching unit 15 for switching an aperture control signal by a lens unit 1 that does not have a built-in lens is called a DC lens, and 15 is a setting button for an operator to set. 18 of the setting button 15 is an upper button, 19 is a lower button, 20 is a left button, 21 is a right button, and 22 is a center button. Reference numeral 16 denotes a remote terminal for inputting a remote control signal for setting automatic sensitivity adjustment from the outside of the image pickup unit 3, and reference numeral 17 denotes a remote control signal input from the remote terminal.

FIG. 2 is a diagram showing a display screen of an embodiment of the television camera of the present invention.
The display screen of FIG. 2 is displayed on the monitor 30. Reference numeral 40 denotes a cursor for selecting a setting item on the display screen when the operator sets automatic sensitivity adjustment (SENSITIVITY CONTROL). Reference numeral 41 denotes a selection bar for selecting a lens (LENS) to be set. When the selected lens is a VIDEO lens, “VIDEO” is selected, and when the selected lens is a DC lens, “DC” is selected. Reference numeral 42 denotes a setting bar for setting the set value of the video signal level (VIDEO LEVEL) output from the combining unit 8 on the display screen. Reference numeral 43 denotes a setting bar for setting the maximum aperture ratio (MAX IRIS) of the diaphragm mechanism of the lens unit 1. In this embodiment, “VIDEO LEVEL” and “MAX IRIS” are set using the setting bar. However, a numerical setting method may be used. “AGC1”, “AGC2”, and “AGC3” are an embodiment for performing setting when the gain control range of AGC5 in FIG. 1 is divided into three. “CCD GAIN1” and “CCD GAIN2” are an example in which settings are made when the electronic amplification control range of the EM-CCD 4 in FIG. 1 is divided into two. From the top of the display, the arrangement order of “AGC1”, “CCD GAIN1”, “AGC2”, “CCD GAIN2”, “AGC3” is an example showing the order of control (described later).

Next, an embodiment of the operation of the present invention will be described with reference to FIG.
In FIG. 1, light from a subject (not shown) enters the lens unit 1. The lens unit 1 adjusts the amount of incident light with a lens diaphragm and forms an image on the EM-CCD 4 of the imaging unit 3. The EM-CCD 4 photoelectrically converts the imaged light and outputs it to the AGC 5. The AGC 5 performs adaptive gain adjustment on the input signal and outputs it to the video processing unit 6. The video processing unit 6 executes various image processing such as edge enhancement and white balance adjustment on the input signal in accordance with the signal output from the CPU 13 and outputs it to the ENC 7 and the lens aperture control unit 12. The ENC 7 converts the input signal into a video signal of the NTSC system or PAL system and outputs it to the combining unit 8. The synthesizer 8 synthesizes the character signal output from the character signal generator 14 with the input video signal and outputs it to the monitor 30. The monitor 30 displays the input signal as an image. The lens diaphragm control unit 12 compares the video signal level setting value input from the CPU 13 with the signal a input from the video processing unit 6, and the video input from the CPU 13 with the signal a input from the video processing unit 6. The output level is increased or decreased until it falls within the range of the signal level setting range value, the signal c is output to the amplifier unit 11, and the signal b is output to the switching unit 10. The amplifier unit 11 amplifies the input signal c and outputs a signal d to the switching unit 10. The switching unit 10 follows the instruction of the CPU 13 and selects the signal b input from the lens aperture control unit 12 when the lens unit 1 is a VIDEO lens, and the signal input from the amplifier unit 11 when the lens unit 1 is a DC lens. d is selected and output to the aperture control unit 2 of the lens unit 1. The aperture controller 2 controls the lens aperture mechanism of the lens unit 1 according to the input signal e to adjust the amount of incident light.

  Note that the switching of the switching unit 10 is performed by the CPU 13 recognizing the setting of a selector switch (not shown). Alternatively, the impedance of the aperture controller 2 is measured by a lens identification unit (not shown), and the CPU 13 automatically determines and switches the lens based on the measurement result. Either switching means may be used.

Next, an embodiment of automatic sensitivity adjustment according to the present invention will be described with reference to FIGS. In this description, the lens unit 1 is a DC lens.
In FIG. 1, the operator can compositely display the display screen of FIG. 2 on the subject image displayed on the monitor 30 by pressing the center button 22 of the setting button 15 composed of, for example, five buttons.

  Then, the operator presses the upper button 18 or the lower button 19 of the setting button 15 while looking at the display screen of FIG. 2 displayed on the monitor 30 to move the cursor 40 to the item “LENS”, and then the setting button 15 The left button 20 or the right button 21 is pressed to move the selection bar 41 to the “DC” position.

  Next, the operator presses the lower button 19 of the setting button 15 to move the cursor 40 to the item “VIDEO LEVEL”. Next, the left button 20 or the right button 21 of the setting button 15 is pressed to move the setting bar 42 to a desired position. When the setting bar 42 is moved to the left, the subject image becomes darker, and when it is moved to the right, the subject image becomes brighter. In this operation, the CPU 13 recognizes the button of the setting button 15 pressed by the operator and displays the position of the setting bar 42 on the display screen from the character signal generator 14. Further, the CPU 13 generates a video signal level setting value from the position of the setting bar 42 and outputs it to the lens aperture controller 12. The lens diaphragm control unit 12 compares the video signal level setting value input from the CPU 13 with the signal a input from the video processing unit 6, and the video input from the CPU 13 with the signal a input from the video processing unit 6. The level of the signal a is increased or decreased by a predetermined amount until the signal level setting value falls within a predetermined range, and the signal c is output to the amplifier unit 11 and the signal b is output to the switching unit 10. The amplifier unit 11 amplifies the input signal c and outputs the signal d to the switching unit 10. The switching unit 10 selects the signal d and outputs the signal e to the aperture control unit 2 of the lens unit 1. The aperture controller 2 controls the lens aperture mechanism of the lens unit 1 according to the input signal e to adjust the amount of incident light. The level of the signal b and the signal c output from the lens aperture control unit 12 is increased or decreased by a predetermined amount. The lens aperture mechanism is opened / closed by a predetermined amount with respect to a predetermined level increase / decrease.

  Next, the operator presses the lower button 19 of the setting button 15 to move the cursor 40 to the item “MAX IRIS”. Next, the left button 20 or the right button 21 of the setting button 15 is pressed to move the setting bar 43 to a desired position. When the setting bar 43 is moved to the left, the maximum aperture ratio of the lens aperture mechanism is set in the closing direction, and when it is moved to the right, the maximum aperture ratio of the lens aperture mechanism is set in the open direction and set to the “OPEN” position. Then, the maximum aperture ratio of the lens aperture mechanism is fully open. In this operation, the CPU 13 recognizes the button of the setting button 15 pressed by the operator and displays the position of the setting bar 43 on the display screen from the character signal generator 14. Further, from the position of the setting bar 43, the CPU 13 limits the maximum levels of the signal b and the signal e output from the lens aperture control unit 12. By limiting the maximum levels of the signals b and e, the maximum aperture ratio of the lens diaphragm mechanism can be set to the position of the setting bar 43. Regarding the relationship between the aperture ratio of the lens diaphragm mechanism of the lens unit 1 and the position of the setting bar 43, the correction value obtained by actual measurement is stored in the CPU 13 in advance, so that the lens diaphragm mechanism is fully closed and the setting bar 43 is “CLOSE”. And the fully open position of the lens aperture mechanism and the “OPEN” position of the setting bar 43 can be matched. Note that the items of “VIDEO LEVEL” and “MAX IRIS” in FIG. 2 can be set for each VIDEO lens and DC lens.

Further, the operator performs setting of automatic sensitivity adjustment with an optimum image quality priority.
1 is divided into a gain control range (0 to 40 dB in this embodiment), and an electron multiplication control range (0 to 66 dB in this embodiment) of the EM-CCD 4 in FIG. The order of control is determined in advance by calculation of signal-to-noise ratio (S / N) or the like or actual measurement. In one embodiment of the present invention, as shown in FIG. 2, the gain control range of the AGC 5 is divided into three, and the control names after division are “AGC1”, “AGC2”, and “AGC3”. The electron multiplication control range of the EM-CCD 4 is divided into two, and the control names after the division are “CCD GAIN1” and “CCD GAIN2”. The order of control is “AGC1”, “CCD GAIN1”, “AGC2”, “CCD GAIN2”, “AGC3”.

  The operator presses the lower button 19 of the setting button 15 to move the cursor 40 to the item “AGC1”, and presses the left button 20 or the right button 21 to set the setting value to “MAX 10 dB” (control in the range of 0 to 10 dB). To do. Next, the operator presses the lower button 19 of the setting button 15 to move the cursor 40 to the item “CCD GAIN1”, and presses the left button 20 or the right button 21 to set the set value to “MAX 40 dB” (in the range of 0 to 40 dB). Control). Next, the operator presses the lower button 19 of the setting button 15 to move the cursor 40 to the item “AGC2”, and presses the left button 20 or the right button 21 to control the set value to “MAX 20 dB” (in the range of 10 to 20 dB). ). Next, the operator presses the lower button 19 of the setting button 15 to move the cursor 40 to the item “CCD GAIN2”, and presses the left button 20 or the right button 21 to set the set value to “MAX 66 dB” (in the range of 40 to 66 dB). Control). Next, the operator presses the lower button 19 of the setting button 15 to move the cursor 40 to the item “AGC3”, and presses the left button 20 or the right button 21 to control the set value to “MAX 40 dB” (in the range of 20 to 40 dB). ).

Next, the operation of an embodiment of the automatic sensitivity adjustment according to the present invention will be described with reference to FIGS.
In this description, the lens unit 1 is a DC lens. When the lens unit 1 is a VIDEO lens, the lens diaphragm mechanism can be controlled by the switching described above.

  FIG. 3 is a diagram showing the relationship between subject illuminance and sensitivity control when the automatic sensitivity adjustment of FIG. 2 is set. The sensitivity to subject illuminance from “starlight” to “noonday sun” is shown. It is one Example which showed the operation | movement of control.

4 and 5 are flowcharts for explaining the sensitivity control of FIG. Connections in the flowcharts of FIGS. 4 and 5 are made with connection symbols “A” and “B”.
The CPU 13 starts control from “START” in FIG. 4, initially sets a gain control value of 0 dB to the drive unit 9 that controls the gain of electron multiplication of the EM-CCD 4 in step S <b> 1, and sets the gain control value of AGC 5 to 0 dB. Is initialized. In step S <b> 2, the lens aperture controller 12 compares the video signal level setting value input from the CPU 13 with the signal a input from the video processor 6, and the signal a input from the video processor 6 is input from the CPU 13. The output level is increased or decreased until it falls within a predetermined range (for example, ± 20 mV) of the set value of the video signal level (for example, “550 mV” for “VIDEO LEVEL” in FIG. 2), and the signal c is output to the amplifier unit 11. Output to the switching unit 10. The amplifier unit 11 amplifies the input signal c and outputs a signal d to the switching unit 10. The switching unit 10 selects the signal d input from the amplifier unit 11 according to an instruction from the CPU 13 and outputs the selected signal d to the aperture control unit 2 of the lens unit 1. The aperture controller 2 controls the lens aperture mechanism of the lens unit 1 according to the input signal e to adjust the amount of incident light. This control is performed when the subject illuminance in FIG. 3 is within the “lens aperture control range”. In step S3, the CPU 13 determines from the lens aperture ratio signal f that the aperture value of the lens aperture mechanism of the lens unit 1 is within a predetermined range of the maximum aperture ratio (for example, 99.0%) set by “MAX IRIS” in FIG. 0.2%), and if the determination result is smaller than the set maximum aperture ratio, the process returns to step S2, and if the determination result is equal to or greater than the set maximum aperture ratio, the process proceeds to step S4. In step S4, the CPU 13 instructs the lens aperture control unit 12 so that the aperture value of the lens aperture mechanism of the lens unit 1 is within a predetermined range of the maximum aperture ratio set by “MAX IRIS” in FIG. 2 (for example, 99.0 ± 0.2%). Control to output a signal to be maintained at That is, the lens aperture control unit 12 controls the CPU 13 to control the signal c that maintains the aperture value of the lens aperture mechanism of the lens unit 1 within a predetermined range of the set maximum aperture ratio, and the signal b to the switching unit. 10, the amplifier unit 11 amplifies the input signal c and outputs a signal d to the switching unit 10, and the switching unit 10 selects the signal d input from the amplifier unit 11 in accordance with an instruction from the CPU 13. The aperture control unit 2 controls the lens aperture mechanism of the lens unit 1 according to the input signal e so that the aperture value of the lens aperture mechanism is within a predetermined range of the maximum aperture ratio. To do. In step S5, the CPU 13 controls the gain of the AGC 5 within the set value range (0 to 10 dB) of “AGC1” until the signal “a” falls within a predetermined range (for example, 550 ± 20 mV) of the video signal level set value. This control is performed when the illuminance of the subject in FIG. 3 is “AGC control range 1”. In step S6, the CPU 13 proceeds to step S7 if the gain control value of the AGC 5 is not more than a predetermined value (for example, 0 dB or less of the “AGC1” setting lower limit value), and proceeds to step S8 if not less than the predetermined value (for example, 0 dB or less). In step S7, the CPU 13 sets the gain control value of AGC5 to 0 dB which is the “AGC1” setting lower limit value, and returns to the process of step S2. In step S8, the CPU 13 proceeds to step S9 if the gain control value of the AGC 5 is not less than a predetermined value (for example, 10 dB or more of the “AGC1” setting upper limit value), and returns to the process in step S5 if not more than the predetermined value (for example, 10 dB or more). . In step S9, the CPU 13 sets the gain control value of AGC 5 to 10 dB which is the “AGC1” setting upper limit value, and proceeds to the process of step S10. In step S10, the CPU 13 instructs the drive unit 9 for performing gain control for electron multiplication of the EM-CCD 4 until the signal a is within a predetermined range of the video signal level setting value (for example, 550 ± 20 mV). Gain is controlled within the GAIN1 ”setting range (0 to 40 dB). This control is performed when the subject illuminance in FIG. 3 is “CCD multiplication control range 1”. In step S11, the CPU 13 proceeds to step S12 if the gain control value of the drive unit 9 that performs the gain control of the electron multiplication of the EM-CCD 4 is not more than a predetermined value (for example, 0 dB or less of the “CCD GAIN1” setting lower limit value). If it is not less than (for example, 0 dB or less), the process proceeds to step S13. In step S12, the CPU 13 sets the gain control value of the drive unit 9 that performs the electron multiplication gain control of the EM-CCD 4 to 0 dB which is the “CCD GAIN1” setting lower limit value, and returns to the process of step S5. In step S13, the CPU 13 proceeds to step S14 if the gain control value of the drive unit 9 that performs gain control of electron multiplication of the EM-CCD 4 is greater than or equal to a predetermined value (for example, 40 dB or more of the “CCD GAIN1” set upper limit value). If not (for example, 40 dB or more), the process returns to step S10. In step S <b> 14, the CPU 13 sets the gain control value of the drive unit 9 that performs the electron multiplication gain control of the EM-CCD 4 to 40 dB which is the “CCD GAIN1” setting upper limit value, and proceeds to the process of step S <b> 15 in FIG. 5. In step S15, the CPU 13 controls the gain of the AGC 5 within the set value range (10 to 20 dB) of “AGC2” until the signal “a” falls within a predetermined range (for example, 550 ± 20 mV) of the video signal level set value. This control is performed when the illuminance of the subject in FIG. 3 is “AGC control range 2”. In step S16, the CPU 13 proceeds to step S17 if the gain control value of the AGC 5 is not more than a predetermined value (for example, 10 dB or less of the “AGC2” setting lower limit value), and proceeds to step S8 if not less than the predetermined value (for example, 10 dB or less). In step S17, the CPU 13 sets the gain control value of the AGC 5 to 10 dB which is the “AGC1” setting upper limit value, and returns to the process of step S10 in FIG. In step S18, the CPU 13 proceeds to step S19 if the gain control value of the AGC 5 is greater than or equal to a predetermined value (for example, 20 dB or more of the “AGC2” setting upper limit value), and returns to the process in step S15 if not greater than the predetermined value (for example, 20 dB or greater). . In step S19, the CPU 13 sets the gain control value of AGC 5 to 20 dB which is the “AGC2” setting upper limit value, and proceeds to the process of step S20. In step S20, the CPU 13 instructs the drive unit 9 for performing gain control for electron multiplication of the EM-CCD 4 until the signal a is within a predetermined range of the video signal level setting value (for example, 550 ± 20 mV). Gain is controlled within the GAIN2 ”setting range (40 to 66 dB). This control is performed when the subject illuminance in FIG. 3 is “CCD multiplication control range 2”. In step S21, the CPU 13 proceeds to step S22 if the gain control value of the drive unit 9 that performs the gain control of the electron multiplication of the EM-CCD 4 is less than a predetermined value (for example, 40 dB or less of the “CCD GAIN2” setting lower limit value). If it is not less than 40 dB (for example, 40 dB or less), the process proceeds to step S23. In step S22, the CPU 13 sets the gain control value of the driving unit 9 that performs gain control of electron multiplication of the EM-CCD 4 to 40 dB which is the “CCD GAIN1” setting upper limit value, and returns to the process of step S15. In step S23, the CPU 13 proceeds to step S24 if the gain control value of the drive unit 9 that performs gain control of electron multiplication of the EM-CCD 4 is not less than a predetermined value (for example, 66 dB or more of the “CCD GAIN2” set upper limit value). If not (for example, 66 dB or more), the process returns to step S20. In step S24, the CPU 13 sets the gain control value of the driving unit 9 that performs gain control of electron multiplication of the EM-CCD 4 to 66 dB which is the “CCD GAIN2” setting upper limit value, and proceeds to the process of step S25. In step S25, the CPU 13 controls the gain of the AGC 5 within the set value range (20 to 40 dB) of “AGC3” until the signal “a” falls within a predetermined range (for example, 550 ± 20 mV) of the video signal level set value. This control is performed when the illuminance of the subject in FIG. 3 is “AGC control range 3”. In step S26, the CPU 13 proceeds to step S27 if the gain control value of the AGC 5 is not more than a predetermined value (for example, 20 dB or less of the “AGC2” setting upper limit value), and returns to step S25 if not less than the predetermined value (for example, 20 dB or less). In step S27, the CPU 13 sets the gain control value of AGC5 to 20 dB which is the “AGC2” setting upper limit value, and returns to the process of step S20.

Next, another embodiment of the present invention will be described with reference to FIG.
When the operator wants to set automatic sensitivity adjustment by remote operation, a remote control signal 17 is input to the remote terminal 16 from, for example, a personal computer or an operating device via the Internet. The input remote control signal 17 is input to the CPU 13.

The set value for automatic sensitivity adjustment by remote control is reflected on the display of the display screen of FIG.
2 may be a viewfinder attached to a television camera. In the above embodiment, the character signal shown in FIG. 2 is synthesized with the video signal, but only the character signal may be displayed on the monitor 30.

  Switching of control by automatic sensitivity adjustment of lens aperture control, AGC5 gain control, and EM-CCD4 gain control may be performed after a predetermined time has elapsed to prevent frequent switching operation (hunting phenomenon).

In the above description of the imaging unit 3, the lens unit 1 can use both a DC lens and a VIDEO lens, but the imaging unit 3 may be a DC lens or a VIDEO lens dedicated machine.
As described above, automatic sensitivity adjustment with optimum image quality priority is achieved by automatic sensitivity adjustment when the lens unit 1 which is a lens capable of controlling the aperture of the present invention and the EM-CCD 4 which is an electron multiplying solid-state imaging device are combined. Adjustments can be made.

  Although the present invention has been described in detail above, it is needless to say that the present invention is not limited to the television camera described herein, and can be widely applied to television cameras other than those described above.

The block diagram which shows the structure of one Example of the television camera of this invention. The figure which shows the display screen of one Example of the television camera of this invention. The figure for demonstrating the sensitivity control of one Example of the television camera of this invention. The flowchart for demonstrating operation | movement of one Example of the television camera of this invention. 5 is a flowchart for explaining the operation subsequent to FIG.

Explanation of symbols

  1: lens unit, 2: aperture control unit, 3: imaging unit, 4: EM-CCD, 5: AGC, 6: video processing unit, 7: ENC, 8: synthesis unit, 9: drive unit, 10: switching unit , 11: amplifier, 12: lens aperture controller, 13: CPU, 14: character signal generator, 15: setting button, 16: remote terminal, 17: remote control signal, 30: monitor, 40: cursor, 41: Selection bar, 42, 43: Setting bar.

Claims (2)

A lens unit capable of controlling the aperture ;
An electron multiplier type imaging device that images incident light from the lens unit and outputs a video signal;
An amplification factor control unit for amplifying the video signal at a predetermined amplification factor;
A video signal processing unit for performing predetermined processing on the amplified video signal;
A setting unit for setting a desired level of the video signal, an upper limit value of the aperture of the lens unit, a range of the amplification factor of the amplification factor control unit, and a range of the electron multiplication factor of the electron multiplication type imaging device,
Controlling the lens unit, the amplification factor control unit and the electron multiplying image sensor output from the video signal processing unit;
When the upper limit value of the aperture of the lens unit is exceeded, the aperture value is fixed to the set upper limit value, and the amplification factor of the amplification factor control unit and the electron multiplication factor of the electron multiplying image sensor are set. An electron multiplying type imaging apparatus, wherein control is alternately performed with Comprising a diaphragm controllable lens portion, and the electron multiplying image pickup device for outputting an image signal by imaging an incident light from the lens unit, and a gain controller for amplifying the video signal at a predetermined amplification factor In an electron multiplier type imaging device ,
Set the desired level of the video signal, the upper limit value of the aperture of the lens unit, the range of the amplification factor of the amplification factor control unit and the range of the electron multiplication factor of the electron multiplication type imaging device,
Control the aperture of the lens unit, the amplification factor of the amplification factor control unit and the electron multiplication factor of the electron multiplication type image sensor so that the video signal becomes the level of the set video signal,
When the upper limit value of the aperture of the lens unit is exceeded, the aperture value is fixed to the set upper limit value, and the amplification factor of the amplification factor control unit and the electron multiplication factor of the electron multiplying image sensor are set. The method of adjusting the sensitivity of an electron multiplier type imaging apparatus, characterized in that the control is performed alternately.

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