JP3983126B2 - Imaging device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an imaging apparatus such as a digital camera.
[0002]
[Prior art]
In recent years, an imaging apparatus such as a digital camera using a CCD (Charge Coupled Device) as an imaging element has been widely used. In this case, the drive frequency for reading the image data from the CCD (hereinafter referred to as drive frequency) is such a frequency that the display image for monitoring has a predetermined image quality.
By the way, in recent years, the number of pixels of a CCD has increased remarkably, and accordingly, the number of read data also increases and the drive frequency of the corresponding CCD also rises. Therefore, the increase in the number of pixels results in an increase in current consumption. .
Also, in this type of imaging apparatus, AF (Auto focus) control is performed at the time of imaging, but in order to shorten the entire imaging time required for imaging the subject, driving for acquiring the AF evaluation value of the CCD is performed. It is desirable to increase the frequency. In order to realize this, Japanese Patent Application Laid-Open No. 10-224694 proposes that the vertical scanning speed is made higher than that in the normal time within a certain period when the AF evaluation value of the CCD is read. . However, increasing the drive frequency for acquiring the AF evaluation value of the CCD to shorten the overall imaging time also leads to an increase in power consumption.
[0003]
On the other hand, since a digital camera is often carried and used, a battery is generally used as a power source outdoors, and a commercial power source is generally converted into a direct current by an AC adapter and used as a power source indoors.
In this case, it is known that when a battery is used as a power source, output impedance is higher than when a DC voltage AC-DC converted by an AC adapter is used as a power source.
Moreover, when using a battery as a power source, a lithium ion battery is often used in terms of operation life, but a NiCd or NiMH battery is also relatively used. However, alkaline batteries are often used because they are easily available and advantageous in terms of cost, but alkaline batteries have higher output impedance than lithium ion batteries, NiCd, and NiMH batteries. There is a characteristic.
Furthermore, in this type of imaging apparatus, it is known that the current consumption differs depending on the operation mode during the imaging operation, and for example, the current consumption increases during the zoom operation compared to other operation modes.
[0004]
[Problems to be solved by the invention]
As described above, in this type of imaging apparatus, the allowable current consumption during imaging varies depending on the output impedance of the power supply defined by the characteristics of the power supply. Also, depending on the operation mode during imaging operation, The current consumption will be different.
For this reason, the drive frequency of the image sensor during the imaging operation and the drive frequency of the image sensor at the time of AF evaluation value acquisition are changed according to the operating conditions specified by the characteristics of the power supply and the operation mode, and always correspond to the operating conditions. It is necessary to perform an operation within the allowable current consumption value and to prevent an imaging operation from being disabled or a defective imaging operation from being caused by an excessive current consumption.
On the other hand, in this type of imaging apparatus, in order to obtain a high-quality captured image, it is required to increase the drive frequency of the image sensor during the imaging operation, and in order to shorten the entire imaging time, an AF evaluation value It is required to increase the drive frequency of the image sensor at the time of acquisition.
[0005]
The present invention has been made in view of the current state of operation of this type of imaging apparatus during imaging as described above, and its first object is to cope with changes in operating conditions defined by power supply characteristics and operating modes. An object of the present invention is to provide an imaging device capable of stably capturing a high-quality captured image.
[0006]
In addition, a second object of the present invention is to provide an imaging apparatus capable of acquiring AF evaluation values at a high speed and shortening the entire imaging time in response to changes in operating conditions defined by power supply characteristics. It is in.
[0007]
[Means for Solving the Problems]
  The present inventionTo achieve the first object, ShootingIdentifying characteristics of a power source, an image pickup means for picking up an image of an object, a signal processing means for generating a luminance signal and a color signal of the object and performing signal processing based on an output signal of the image pickup element, and an image element as a constituent element A power supply characteristic identification unit; and an imaging drive frequency control unit configured to change and control a drive frequency of the imaging element during an imaging operation based on the power supply identification information obtained by the power supply characteristic identification unit.In the imaging device, when the identification information of the power supply characteristic is the output impedance information of the power supply, and the output impedance of the power supply is identified to be equal to or higher than a preset upper limit value, the imaging drive frequency control means To control the drive frequency of the drive to be lower than the normal frequencyIt is characterized by this.
[0008]
  According to such means, the subject is imaged by the imaging means having the imaging element as a component, and the signal processing is performed by the signal processing means based on the output signal of the imaging element, and the luminance signal and the color signal of the subject are obtained. Although it is created, the characteristics of the power supply are identified by the power supply characteristic identification means, and the drive frequency of the image sensor during the imaging operation is adapted to the power supply characteristics identified by the power supply characteristic identification means by the imaging drive frequency control means. In the state where the current consumption is controlled properly and the current consumption is properly controlled, the malfunctioning due to the excessive current consumption is prevented, and the imaging operation to obtain high-quality captured images corresponding to the power supply characteristics is stable. Executed.Specifically, the power supply characteristic identification information is output impedance information of the power supply, and when the power supply characteristic identification means identifies that the output impedance of the power supply is greater than or equal to a preset upper limit value, the imaging drive frequency control means The above action is executed by performing control to lower the drive frequency during the imaging operation of the image sensor from the normal frequency.
[0013]
  Similarly, in order to achieve the first object, the present invention also includes an image pickup unit having an image pickup element as a constituent element, an image pickup unit for picking up an image of the object, and a luminance signal and a color signal of the object based on the output signal of the image pickup element A signal processing means for performing signal processing, a power supply characteristic identifying means for identifying a power supply characteristic, and a drive frequency of the image pickup element during an imaging operation based on the identification information of the power supply by the power supply characteristic identifying means In an imaging apparatus having imaging drive frequency control means for change control,When the identification information of the power supply characteristic is the characteristic information of the power supply battery, and the output impedance of the power supply battery is identified as being equal to or higher than a preset upper limit value, the imaging drive frequency control means performs the drive frequency during the imaging operation of the image sensor. The control is performed to lower the frequency below the normal frequency.
[0014]
  According to such means, the subject is imaged by the imaging means having the imaging element as a component, and the signal processing is performed by the signal processing means based on the output signal of the imaging element, and the luminance signal and the color signal of the subject are obtained. Although it is created, the characteristics of the power supply are identified by the power supply characteristic identification means, and the drive frequency of the image sensor during the imaging operation is adapted to the power supply characteristics identified by the power supply characteristic identification means by the imaging drive frequency control means. In the state where the current consumption is controlled properly and the current consumption is properly controlled, the malfunctioning due to the excessive current consumption is prevented, and the imaging operation to obtain high-quality captured images corresponding to the power supply characteristics is stable. Executed. In particular,If the identification information of the power supply characteristic is the characteristic information of the power supply battery, and the output impedance of the power supply battery is identified as being equal to or higher than a preset upper limit value, the imaging drive frequency control means determines the drive frequency during the imaging operation of the image sensor. By controlling to lower than the normal frequency,The above actionIs executed.
[0017]
  Furthermore, in order to achieve the first object, the present invention similarly uses an imaging device as a component, and imaging means for imaging a subject, and a luminance signal and a color signal of the subject based on an output signal of the imaging device. A signal processing means for performing signal processing, an operation mode identification means for identifying an operation mode, and a drive frequency of the image sensor during an imaging operation is changed based on the operation mode identification information by the operation mode identification means In an imaging apparatus having imaging drive frequency control means for controlling,When the operation mode identifying means identifies that the operation mode is the zoom operation mode, the imaging drive frequency control means performs control to lower the drive frequency during the imaging operation of the image sensor from the normal frequency. It is.
[0018]
  According to such means, the subject is imaged by the imaging means having the imaging element as a component, and the signal processing is performed by the signal processing means based on the output signal of the imaging element, and the luminance signal and the color signal of the subject are obtained. The operation mode is identified by the operation mode identification means, and the drive frequency of the image sensor during the imaging operation is adapted to the operation mode identified by the operation mode identification means by the imaging drive frequency control means. In a state where the change control is performed and the current consumption is appropriately set and controlled, the defective operation due to the generation of excessive current consumption is prevented, and the imaging operation for obtaining a high-quality captured image corresponding to the operation mode is stably executed. The In particular,When the operation mode identification unit identifies that the operation mode is the zoom operation mode, the imaging drive frequency control unit performs control to lower the drive frequency during the imaging operation of the image sensor from the normal frequency,The above actionIs executed.
[0019]
  And this inventionTo achieve the second object, ShootingAn imaging device that includes an image element as a component, an evaluation value acquisition unit that acquires an AF evaluation value based on imaging of the subject by the imaging unit, and an output signal of the imaging device based on an output signal of the imaging device A signal processing unit that creates a luminance signal and a color signal and performs signal processing, a power source characteristic identifying unit that identifies a power source characteristic, and an AF evaluation value acquisition time based on the power source identification information by the power source characteristic identifying unit Evaluation value acquisition drive frequency control means for changing and controlling the evaluation value acquisition drive frequency of the image sensor.
[0020]
According to such means, the subject is imaged by the imaging means having the imaging element as a component, and the signal processing is performed by the signal processing means based on the output signal of the imaging element, and the luminance signal and the color signal of the subject are obtained. The power supply characteristic identifying unit identifies the power supply characteristic, and the imaging drive frequency control unit identifies the evaluation value acquisition drive frequency of the image sensor at the time of AF evaluation value acquisition by the power supply characteristic identification unit. Change control is adapted to the characteristics of the power supply, and within the range adapted to the characteristics of the power supply, the evaluation value acquisition drive frequency of the image sensor is increased to speed up the AF evaluation value acquisition control, thereby reducing the overall imaging time. The
[0021]
  The present invention also providesSimilarly to achieve the second objective, ElectricWhen the identification information of the source characteristic is output impedance information of the power source and the output impedance of the power source is identified as being lower than or equal to a preset lower limit value, the evaluation value acquisition drive frequency control means The control is performed to raise the frequency from the normal frequency.
[0022]
  According to such means, when the identification information of the power supply characteristics is output impedance information of the power supply, and the output impedance of the power supply is identified to be equal to or lower than a preset lower limit value, the evaluation value acquisition drive frequency control means By performing control to increase the evaluation value acquisition drive frequency of the normal frequency,The above actionIs executed.
[0023]
  Furthermore, the present invention providesSimilarly to achieve the second objective, ElectricThe identification information of the source characteristic is identification information as to whether the power source is an AC adapter or a battery. When the power source is identified as an AC adapter, the evaluation value acquisition drive frequency control means Control for increasing the acquisition drive frequency from the normal frequency is performed.
[0024]
  According to such means, the identification information of the power supply characteristics is used as identification information on whether the power supply is an AC adapter or a battery. When the power supply is identified as an AC adapter, the evaluation value acquisition drive frequency control means By performing control to increase the evaluation value acquisition drive frequency of the image sensor from the normal frequency,The above actionIs executed.
[0025]
  Furthermore, the present invention providesSimilarly to achieve the second objective, ElectricWhen the identification information of the source characteristic is the characteristic information of the power supply battery, and the output impedance of the power supply battery is identified to be equal to or lower than a preset lower limit value, the evaluation value acquisition drive frequency control means performs the evaluation value acquisition drive of the image sensor. Control is performed to raise the frequency from the normal frequency.
[0026]
  According to such means, when the identification information of the power supply characteristic is the characteristic information of the power supply battery, and the output impedance of the power supply battery is identified to be equal to or lower than a preset lower limit value, the evaluation value acquisition drive frequency control means performs imaging. By performing control to increase the evaluation value acquisition drive frequency of the element from the normal frequency,The above actionIs executed.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
FIG. 1 is a block diagram showing the configuration of the present embodiment, FIG. 2 is an explanatory diagram of changing the drive frequency of the image sensor according to the power supply characteristics in the present embodiment, and FIG. FIG. 4 is an explanatory diagram of the frequency change, and FIG. 4 is an explanatory diagram of the drive frequency change of the image sensor for obtaining the AF evaluation value during the AF control period in the present embodiment.
[0028]
In the present embodiment, as shown in FIG. 1, an AF (Auto Focus) function, a zoom function, and an aperture function are provided, and a filter is provided at the rear stage of the lens unit 1 on which a subject light image is incident. The shutter mechanism unit 2 is disposed, and a CCD (Charge Coupled Device) 5 that has an electronic shutter function and photoelectrically converts and outputs an optical image of a subject is disposed at the subsequent stage of the shutter mechanism unit 2. The imaging signal processing unit 10 is connected to the output terminal of the CCD 5.
The imaging signal processing unit 10 is provided with a CDS (Correlated double sampling circuit) 6 that is connected to the output terminal of the CCD 5 and suppresses noise of the output signal of the CCD 5, and is provided at the output terminal of the CDS 6. Are connected to an AGC 7 for performing automatic gain control, and an AD conversion circuit 8 for performing AD conversion is connected to an output terminal of the AGC 7.
[0029]
At the output terminal of the AD conversion circuit 8, YUV conversion, JPEG (Joint Photographic Experts Group) standard compression / expansion processing, and image processing are performed on the digitized raw signal of the subject optical image output from the AD conversion circuit 8. A signal processing unit 12 is connected to perform various signal processing related to display data creation, and transfer and recording / reading processing of various data.
The signal processing unit 12 controls the signal processing at the time of YUV conversion for creating a luminance signal and a color signal from the Raw signal, and creates an evaluation value related to AF, AE (Auto exposure), white balance, DSP 14, JPEG A JPEG compression / decompression circuit 15 that performs standard data compression / decompression and a video DA conversion circuit 16 that performs conversion output of image display data are provided.
The signal processing unit 12 is connected to an SDRAM 17 in which Raw signal data, YUV converted signal data, and JPEG standard compressed data are written and read out, and the video DA conversion circuit 16 of the signal processing unit 12 is connected to various types of signals. A liquid crystal display 18 for displaying the data is connected.
[0030]
On the other hand, the present embodiment is provided with a CPU 22 that controls the overall operation. The CPU 22 is connected to an operation unit 23 for inputting various command signals by an operator, and an AC adapter 24 or a battery serving as a power source. 26 is connected via a changeover switch 27, and a DC-DC converter that supplies a predetermined DC voltage to each part is connected to an output terminal of the changeover switch 27.
The output terminal of the CPU 22 is connected to the motor 3 for driving and controlling the lens unit 1 and the shutter mechanism unit 2 and the imaging signal processing unit 10. Further, the CPU 22 has a control program and AF control distance measurement. An EEPROM 21 in which element data and adjustment value data are stored, a memory card 20 in which compressed image data is recorded, and a signal processing unit 12 are connected to be able to exchange signals.
The CPU 22 processes a command signal input from the operation unit 23 by the operator, performs various calculations including AF, AE, and white balance calculations, and sends parameters to the motor 3, the imaging signal processing unit 10, and the signal processing unit 12. Furthermore, the drive frequency of the CCD 5 or the AF evaluation value acquisition drive frequency of the CCD 5 is changed and controlled according to the characteristics of the power source used or the identification information of the operation mode, and the overall operation is controlled through these processes. It has a function to do.
[0031]
Further, in the present embodiment, a clock generator 13 that operates according to a control signal input from the CPU 22 and outputs a clock to the imaging signal processing unit 10 is provided, and the control signal from the CPU 22 and the clock generator 13 A timing generator 11 is provided which receives a clock and supplies a timing signal to the CCD 5 and the imaging signal processing unit 10.
[0032]
The imaging operation of the present embodiment having such a configuration is performed as follows.
When the imaging operation is started, the CPU 22 inputs a drive control signal to the motor 3 and a control signal to the imaging signal processing unit 10 and the signal processing unit 12 based on a command signal from the operation unit 23.
The aperture is set in the lens unit 1 by the motor 3, and AF control is performed on the incident light image from the subject. When zoom setting is performed, the zoom operation is controlled, and the shotta mechanism unit is controlled. 2 is subjected to exposure control.
A subject light image incident on the CCD 5 from the shirter mechanism 2 is arranged in a matrix on the CCD 5 based on a drive signal supplied to the CCD 5 via the clock generator 13 and the timing generator 11 by a control signal from the CPU 22. The light is incident on the photodiode, and the accumulation time is controlled and accumulated by the electronic shutter operation.
[0033]
Based on this electronic shotter operation, the incident light image of the subject is converted into an analog electrical signal by the CCD 5 and output from the CCD 5, subjected to low noise processing by correlated double sampling by the CDS 6, input to the AGC 7, and leveled by the AGC 7. After the correction is performed, the AD conversion circuit 8 performs AD conversion at a sampling frequency that is an integral multiple of the subcarrier frequency of the NTSC signal, for example, and inputs the signal to the signal processing unit 12.
In this way, the digital signal of the subject optical image input to the signal processing unit 12 is first stored in the SDRAM 17 as Raw signal data in the CCD array.
[0034]
Then, the signal processing unit 12 performs YUV conversion for creating a color difference signal and a luminance signal based on gamma processing and color separation processing on the Raw signal read from the SDRAM 17 in accordance with a command from the CPU 22, and obtains the obtained color difference signal and A digital NTSC signal is acquired from the luminance signal, and this digital NTSC signal is DA-converted by the video DA conversion circuit 16 and displayed on the liquid crystal display 18 as a subject image signal.
[0035]
On the other hand, when the captured image data of the subject is stored in the memory card 20, the Raw signal data read from the SDRAM 17 is YUV converted by the signal processing circuit 12, and orthogonal conversion or Huffman encoding is performed by the JPEG compression / decompression circuit 15. The data is compressed by the JPEG method and stored in the SDRAM 17 as JPEG compressed data. Then, the JPEG compressed data read from the SDRAM 17 is written and recorded in the memory card 20 in accordance with a command from the CPU 22.
[0036]
When the image data recorded on the memory card 20 is read and displayed, the JPEG compressed data read from the memory card 20 is first written to the SDRAM 17 by the command of the CPU 22 and is then written by the command of the CPU 22. The JPEG compressed data read from the SDRAM 17 is expanded in real time by the compression / decompression circuit 15 to obtain a digital NTSC signal. Next, the obtained digital NTSC signal is converted into an analog signal by the video DA conversion circuit 16 and displayed on the liquid crystal display 18.
[0037]
In such an imaging operation, in the present embodiment, the characteristics of the power source used by the CPU 22 and the operation mode of the apparatus are identified, and based on the obtained identification information, the driving frequency of the CCD 5 or the AF evaluation value acquisition driving frequency. Is controlled to change.
First, the operation in the drive frequency change mode in which the drive frequency of the CCD 5 is changed and controlled will be described.
In the present embodiment, as shown in FIG. 1, the AC switch 24 is used as a power source when used indoors by switching the changeover switch 27, and the battery 26 is used as a power source when used outdoors. Is used.
In the present embodiment, the CPU 22 identifies whether the AC adapter 24 is used for the power source or the battery 26 having a higher output impedance than the AC adapter 24 by comparison with a preset reference resistance value. Is done. If the battery 26 is identified as being used, the CPU 22 compares the output impedance of the battery 26 with a preset reference resistance value, and the lithium ion battery or NiCd, which has a relatively low output impedance. It is discriminated whether a NiMH battery is used or an alkaline battery with a high output impedance is used.
[0038]
When it is determined that a DC voltage from the AC adapter 24 having a relatively low output impedance and a sufficient current consumption is used as a power source, as shown in FIG. The frequency of the drive signal fd for data reading is set to a preset normal reference value, and the CCD 5 is driven by the set drive frequency. Then, the output signal F1 photoelectrically converted from the CCD 5 is fetched in accordance with the set drive frequency, and the image signal Fm corresponding to the fetched output signal F1 is dense and high-quality subject image on the liquid crystal display 18. Is displayed.
On the other hand, when it is determined that a battery 26 having a high output impedance and no sufficient current consumption is used as a power source as compared with the AC adapter 24, as shown in FIG. Compared to the case where is used, the frequency of the drive signal fd at the time of reading data of the CCD 5 during the imaging operation is changed to a lower frequency value than the normal reference value, and the CCD 5 is driven by the set drive frequency. The Then, the output signal F1 photoelectrically converted from the CCD 5 is fetched corresponding to the set low driving frequency, and the image signal Fm corresponding to the fetched output signal F1 prevents the defective display operation on the liquid crystal display 18. And displayed as a subject image of stable quality.
[0039]
When the battery 26 is used as a power source, the CPU 22 determines that a lithium ion battery, NiCd, or NiMH battery having a relatively low output impedance is used, or an alkaline battery having a high output impedance is used. Depending on whether or not it is determined, the CCD 5 during the imaging operation is driven by the drive signals having different frequencies, as in the case of the AC adapter 34 and the battery 26 described with reference to FIG. Image display is performed in which current consumption is suppressed and defective display of the subject image is prevented.
[0040]
Further, in the present embodiment, the CPU 22 identifies whether or not the operation mode is a case where the current consumption is large. For example, if the CPU 22 identifies that the current mode is a case where the current consumption is large such as a zoom operation, the zoom operation is performed. If not, as shown in FIG. 3 (a), as shown in FIG. 3 (b), as shown in FIG. 3 (b), as shown in FIG. In the operation mode execution period Td, the frequency of the drive signal fd is decreased below the normal reference value, the CCD 5 is driven, and image display is performed while suppressing current consumption and preventing defective display of the subject image.
[0041]
Next, the operation in the AF evaluation value acquisition drive frequency change mode in which the AF evaluation value acquisition drive frequency of the CCD 5 of this embodiment is controlled to be changed will be described. .
In the present embodiment, when the CPU 22 determines that the battery 26 having a relatively high output impedance and no current consumption is used as the power source, as shown in FIG. The frequency of the drive signal fd of the CCD 5 when acquiring the AF evaluation value in the section Tafo is set to a preset normal reference value, and the CCD 5 is driven by the set drive frequency. Then, the output signal F1 photoelectrically converted is output from the CCD 5 corresponding to the set drive frequency, and the evaluation value output Faf corresponding to the output signal F1 is acquired in the AF control section Tafo.
[0042]
On the other hand, when it is determined that the DC output voltage of the AC adapter 24 having a low output impedance and sufficient current consumption as compared with the battery 26 is used as a power source, as shown in FIG. The frequency of the drive signal fd of the CCD 5 at the time of obtaining the AF evaluation value is changed to a higher frequency value than the normal reference value when the battery 26 is used, and the AF evaluation value acquisition section Taf is changed according to the changed drive frequency. When the AF evaluation value is acquired, the CCD 5 is driven.
In the AF evaluation value acquisition section Taf (<Tafo), the output signal F1 photoelectrically converted from the CCD 5 is taken in correspondence with the set high driving frequency, and the evaluation value output Faf corresponding to the output signal F1 is taken. Is acquired at a high speed in the shortened AF control section Taf.
[0043]
When the battery 26 is used as a power source, the CPU 22 determines that a lithium ion battery, NiCd, or NiMH battery having a relatively low output impedance is used, or an alkaline battery having a high output impedance is used. Thus, in the same way as the case of the AC adapter and battery described with reference to FIG. 2, the CCD 5 is driven at the time of obtaining the AF evaluation value by drive signals having different frequencies, and the output impedance is low. When the battery is used, the AF control section Taf is shortened, and the AF evaluation value is acquired at a high speed.
[0044]
As described above, according to the present embodiment, the CPU 22 identifies the output impedance characteristics of the power supply by the magnitude of the output impedance in the range of the battery type due to the difference between the AC adapter and the battery. The operation mode with a large current consumption is identified, and the frequency of the drive signal of the CCD 5 during the imaging operation is higher than the normal frequency when the output impedance of the power source exceeds a predetermined reference value and during the period of the operation mode with a large current consumption. In accordance with the output impedance characteristics of the power supply, the subject can always be imaged with stable image quality by selecting the correct current consumption that prevents the occurrence of defective operation in the operation mode with large current consumption. Is possible.
At the same time, according to the present embodiment, due to the difference between the AC adapter identified by the CPU 22 and the battery, the output impedance of the power supply is less than or equal to a predetermined reference value based on the power supply characteristic information based on the magnitude of the output impedance in the range over the battery type In this case, the drive frequency of the CCD 5 at the time of acquiring the AF evaluation value is increased from the normal frequency, the AF evaluation value acquisition time is performed at a high speed, and the entire imaging time can be shortened.
[0045]
【The invention's effect】
According to the present invention, an imaging device that provides the following effects (1) to (10) is provided.
(1)A subject is imaged by an imaging means having an imaging element as a component, and signal processing is performed by a signal processing means based on an output signal of the imaging element to generate a luminance signal and a color signal of the subject. The identification means identifies the characteristics of the power supply, and the imaging drive frequency control means controls and changes the drive frequency of the image sensor during the imaging operation in accordance with the power supply characteristics identified by the power supply characteristic identification means. It is possible to stably perform an imaging operation to obtain a high-quality captured image corresponding to the power supply characteristics by preventing a defective operation due to excessive current consumption while the current is appropriately set and controlled. .
[0046]
(2)The power supply characteristic identification information is output impedance information of the power supply, and when the power supply characteristic identification means identifies that the output impedance of the power supply is equal to or higher than a preset upper limit value, the imaging drive frequency control means performs the imaging operation of the image sensor. To control the driving frequency to be lower than the normal frequencyTherefore, the above (1)It is possible to achieve the effects obtained with
[0047]
(3)The power supply characteristic identification information is information indicating whether the power supply is an AC adapter or a battery. When the power supply characteristic identifying means identifies that the power supply is a battery, the imaging drive frequency control means By controlling the driving frequency to be lower than the normal frequencyAbove (1)It is possible to achieve the effects obtained with
[0048]
(4)If the identification information of the power supply characteristic is the characteristic information of the power supply battery, and the output impedance of the power supply battery is identified as being equal to or higher than a preset upper limit value, the imaging drive frequency control means determines the drive frequency during the imaging operation of the image sensor. By controlling to lower than the normal frequency,Above (1)It is possible to achieve the effects obtained with
[0049]
(5)The subject is imaged by the imaging means including the imaging element, and the signal processing means performs signal processing based on the output signal of the imaging element to generate the luminance signal and the color signal of the subject. The operation mode is identified by the identification means, and the drive frequency of the image sensor during the imaging operation is changed and controlled in accordance with the operation mode identified by the operation mode identification means by the imaging drive frequency control means. It is possible to stably perform an imaging operation for obtaining a high-quality captured image corresponding to the operation mode by preventing a defective operation due to the generation of excessive current consumption in a state where the setting control is appropriately performed.
[0050]
(6)When the operation mode identification unit identifies that the operation mode is the zoom operation mode, the imaging drive frequency control unit performs control to lower the drive frequency during the imaging operation of the image sensor from the normal frequency,Above (5)It is possible to achieve the effect obtained with.
[0051]
(7)A subject is imaged by an imaging means having an imaging element as a component, and signal processing is performed by a signal processing means based on an output signal of the imaging element to generate a luminance signal and a color signal of the subject. The characteristic of the power source is identified by the identification unit, and the evaluation value acquisition driving frequency of the image sensor at the time of acquiring the AF evaluation value is adapted to the characteristic of the power source identified by the power characteristic identification unit by the imaging driving frequency control unit. The entire imaging time can be shortened by increasing the AF evaluation value acquisition control by increasing the evaluation value acquisition drive frequency of the imaging device within a range that is controlled by change and adapted to the characteristics of the power supply.
[0052]
(8)When the identification information of the power supply characteristic is output impedance information of the power supply, and the output impedance of the power supply is identified as being equal to or lower than a preset lower limit value, the evaluation value acquisition drive frequency control means determines the evaluation value acquisition drive frequency of the image sensor. By performing control to raise the frequency above the normal frequency,Above (7)It is possible to achieve the effect obtained with.
[0053]
(9)The identification information of the power supply characteristic is used as identification information indicating whether the power supply is an AC adapter or a battery. When the power supply is identified as an AC adapter, the evaluation value acquisition drive frequency control means performs evaluation value acquisition drive of the image sensor. By controlling the frequency to be higher than the normal frequency,Above (7)It is possible to achieve the effect obtained with.
[0054]
(10)When the identification information of the power supply characteristic is the characteristic information of the power supply battery, and the output impedance of the power supply battery is identified to be equal to or lower than a preset lower limit value, the evaluation value acquisition drive frequency control means performs evaluation value acquisition drive frequency of the image sensor. By controlling to raise the frequency above the normal frequency,Above (7)It is possible to achieve the effect obtained with.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an embodiment of the present invention.
FIG. 2 is an explanatory diagram of changing the drive frequency of the image sensor according to power supply characteristics in the embodiment.
FIG. 3 is an explanatory diagram of changing the drive frequency of the image sensor according to the operation mode in the embodiment.
FIG. 4 is an explanatory diagram of a change in driving frequency of an image sensor for obtaining an AF evaluation value during an AF control period in the embodiment.
[Explanation of symbols]
1 Lens part
2 SHOTTA mechanism
10 Imaging signal processing unit
11 Timing generator
12 Signal processing unit
13 Clock generator
14 DSP
15 JPEG compression / decompression circuit
16 Video DA converter
17 SDRAM
18 Liquid crystal display
21 EEPROM
22 CPU
24 AC adapter
26 batteries

Claims (7)

An imaging means having an imaging element as a component, and imaging an object;
Signal processing means for generating a luminance signal and a color signal of the subject based on the output signal of the image sensor and performing signal processing;
A power source characteristic identifying means for identifying a power source characteristic;
Imaging drive frequency control means for changing and controlling the drive frequency of the image sensor during an imaging operation based on the identification information of the power source by the power supply characteristic identification means;
In an imaging apparatus characterized by having:
When the identification information of the power supply characteristic is the output impedance information of the power supply, and the output impedance of the power supply is identified as being equal to or higher than a preset upper limit value, the imaging drive frequency control means determines the drive frequency during the imaging operation of the image sensor. An imaging apparatus that performs control to lower the frequency below a normal frequency. An imaging means having an imaging element as a component, and imaging an object;
Signal processing means for generating a luminance signal and a color signal of the subject based on the output signal of the image sensor and performing signal processing;
A power source characteristic identifying means for identifying a power source characteristic;
Imaging drive frequency control means for changing and controlling the drive frequency of the image sensor during an imaging operation based on the identification information of the power source by the power supply characteristic identification means;
In an imaging apparatus characterized by having:
When the identification information of the power supply characteristic is the characteristic information of the power supply battery, and the output impedance of the power supply battery is identified as being equal to or higher than a preset upper limit value, the imaging drive frequency control means performs the drive frequency during the imaging operation of the image sensor. An image pickup apparatus that performs control to lower the frequency below a normal frequency. An imaging means having an imaging element as a component, and imaging an object;
Signal processing means for generating a luminance signal and a color signal of the subject based on the output signal of the image sensor and performing signal processing;
An operation mode identifying means for identifying the operation mode;
Imaging drive frequency control means for changing and controlling the drive frequency of the image sensor during the imaging operation based on the identification information of the operation mode by the operation mode identification means;
In an imaging apparatus characterized by having:
When the operation mode identification unit identifies that the operation mode is the zoom operation mode, the imaging drive frequency control unit performs control to lower the drive frequency during the imaging operation of the image sensor from a normal frequency. apparatus. An imaging means having an imaging element as a component, and imaging an object;
Evaluation value acquisition means for acquiring an AF evaluation value based on imaging of the subject by the imaging means;
Signal processing means for generating a luminance signal and a color signal of the subject based on the output signal of the image sensor and performing signal processing;
A power source characteristic identifying means for identifying a power source characteristic;
Evaluation value acquisition drive frequency control means for changing and controlling the evaluation value acquisition drive frequency of the image sensor at the time of AF evaluation value acquisition based on the power supply identification information by the power supply characteristic identification means. apparatus. 5. The imaging apparatus according to claim 4, wherein when the identification information of the power supply characteristic is output impedance information of the power supply and the output impedance of the power supply is identified to be equal to or lower than a preset lower limit value, the evaluation value acquisition drive frequency control means An image pickup apparatus that performs control to increase an evaluation value acquisition drive frequency of the image pickup element from a normal frequency. 5. The imaging device according to claim 4 , wherein the identification information of the power supply characteristic is identification information indicating whether the power supply is an AC adapter or a battery, and if the power supply is identified as an AC adapter, the evaluation value acquisition drive frequency An image pickup apparatus, wherein the control means performs control to raise an evaluation value acquisition drive frequency of the image pickup device from a normal frequency. 5. The imaging apparatus according to claim 4 , wherein the identification information of the power supply characteristic is the characteristic information of the power supply battery, and if the output impedance of the power supply battery is identified to be equal to or less than a preset lower limit value, the evaluation value acquisition drive frequency control means However, the image pickup apparatus performs control to increase the evaluation value acquisition drive frequency of the image pickup device from the normal frequency.

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