JP2014171002A - Image pickup device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image pickup device capable of precisely predicting a rise of temperature of an electronic component even in different usage environments.SOLUTION: A camera 1 comprises: a storage unit 9 in which the outputs of temperature sensors 31, 41, 51 for detecting the temperature data of an image pickup element 3, an image processing unit 4, a secondary battery 5, and an image pickup element 3 OB part and the output of the image pickup element 3 OB, as well as information about the upper-limit usage temperatures of the image pickup element 3, the image processing unit 4, the secondary battery 5, and the OB part of the image pickup element 3 are stored; and a control unit 10 for calculating a predicted outside air temperature of the camera 1 on the basis of the temperature data of the temperature sensors 31, 41, 51 and OB output, and calculating a remaining usable time of the image pickup element 3, the image processing unit 4, the secondary battery 5, and the image pickup element 3 OB part on the basis of information about the calculated predicted outside air temperature, the temperature data, and the upper-limit usage temperature.

Description

  The present invention relates to an imaging apparatus.

Conventionally, in order to prevent damage to the camera due to abnormal heat generation of the mounted electronic components, the temperature can be used based on the detection information of the temperature sensor provided on the electronic components (for example, rechargeable battery) of the camera A camera that predicts a time exceeding a certain upper limit temperature and issues a warning has been proposed (for example, Patent Document 1).
However, since this camera predicts the time exceeding the upper limit of use temperature based only on the temperature information of the temperature detector provided in the rechargeable battery, it is predicted by the temperature of the camera's usage environment, that is, the influence of the outside air temperature. The time spent was inaccurate.

JP 2009-27419 A

  An object of the present invention is to provide an imaging device capable of accurately predicting a temperature rise of an electronic component even under different use environments.

In order to solve the above-mentioned problem, the invention of claim 1 is a photographing apparatus equipped with an electronic component, and stores a temperature detection unit for detecting the temperature of the electronic component and information on the upper limit temperature of use of the electronic component. And calculating the outside air temperature of the photographing apparatus based on the temperature detection information of the storage unit and the temperature detecting unit, and based on the calculated outside air temperature information, the temperature detection information, and the use upper limit temperature information And a control unit that calculates the remaining usable time of the electronic component.
According to a second aspect of the present invention, in the photographing apparatus according to the first aspect, the storage unit stores temperature change information indicating a temperature change per unit time of the electronic component with respect to an outside temperature of the photographing apparatus, and the control The unit is an imaging device that calculates the outside air temperature based on the temperature change information and the temperature detection information.
According to a third aspect of the present invention, in the photographing apparatus according to the second aspect, the temperature detection unit is provided in each of the plurality of electronic components of the photographing apparatus, and the control unit is associated with each of the temperature detection units. The outside air temperature is calculated, the average value of the calculated outside air temperature is calculated, the calculated average value, each temperature detection information of the temperature detection unit, and information on each use upper limit temperature of the electronic component, Based on the above, the usable time of each electronic component is calculated.
According to a fourth aspect of the present invention, in the photographing apparatus according to the third aspect, the control unit calculates an average value of the outside air temperature by excluding an outside air temperature having low reliability from the calculated outside air temperature. The imaging device characterized by the above.

  According to the present invention, it is possible to accurately predict a temperature rise of an electronic component even under different usage environments.

It is the schematic which shows the whole structure of the camera 1 of embodiment. It is a block diagram explaining the whole structure of the camera 1 of embodiment. It is a figure explaining the information of the temperature change memorize | stored in the memory | storage part 9 of the camera 1 of embodiment. It is a flowchart explaining the calculation process of the outside temperature after the power supply interruption of the camera 1 of the embodiment. It is a flowchart explaining the operation | movement after power activation of the camera 1 of embodiment.

(Embodiment)
Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a schematic diagram illustrating an overall configuration of a camera 1 according to the embodiment.
FIG. 2 is a block diagram illustrating the overall configuration of the camera 1 according to the embodiment.
FIG. 3 is a diagram illustrating temperature change information stored in the storage unit 9 of the camera 1 according to the embodiment. FIG. 3A is a diagram showing a locus of temperature change with time of each part of the camera 1 at an outside air temperature of 20 ° C., and FIG. 3B is a temperature change slope and outside air temperature of each part of the camera 1. It is a figure which shows the relationship.
In FIG. 3A, the vertical axis indicates the measured temperature of the image sensor 3, the image processing unit 4, the rechargeable battery 5, and the OB unit (described later) of the image sensor 3, and the horizontal axis indicates the camera 1 is turned on. Indicates the elapsed time after.

As shown in FIGS. 1 and 2, the camera (photographing device) 1 includes a lens unit 2, an image sensor 3, an image processing unit 4, a rechargeable battery 5, a display unit 6, an operation unit 7, a shutter unit 8, and a storage unit 9. A digital camera including the control unit 10 and the like.
A part of the electronic parts constituting the camera 1 is provided with a temperature sensor that detects temperature data of the electronic parts. In the present embodiment, temperature sensors 31, 41, 51 are provided in the imaging device 3, the image processing unit 4, and the rechargeable battery 5, respectively.
As shown in FIG. 1, the lens unit 2 is provided at the front of the camera 1. The lens unit 2 receives light A <b> 1 of the subject, enlarges or reduces the subject image according to the shooting purpose, and emits the image to the image sensor 3. This is a lens group having a zoom function.
The imaging element 3 is a photoelectric conversion element such as a CCD or a CMOS, and has a rectangular imaging area composed of a plurality of pixels. Then, the image sensor 3 converts the image formed on the imaging surface into an electric signal and outputs an image signal corresponding to the subject image to the image processing unit 4.

The image processing unit 4 is a part that performs image processing such as interpolation, gradation conversion, and edge enhancement on the image signal input from the image sensor 3. Further, the image processing unit 4 detects a dark current output (hereinafter referred to as an OB output) of an optical black portion (hereinafter referred to as an OB unit) of the image sensor 3 and outputs it to the control unit 10.
The rechargeable battery 5 is a rechargeable battery that supplies power to each part of the camera 1.
The display unit 6 is a liquid crystal monitor that displays a photographed subject image or displays a setting screen of the camera 1, and is provided on the back surface of the camera 1.
The operation unit 7 is a release switch that is provided in the upper part of the camera 1 and executes photographing of a subject image. The operation unit 7 outputs operation information to the control unit 10.
The shutter unit 8 is disposed between the lens unit 2 and the image sensor 3. The shutter unit 8 includes a plurality of shutter blade groups (not shown), opens and closes the shutter blade groups according to the operation of the operation unit 7, and causes the light A 1 incident from the lens unit 2 to enter the image sensor 3.

The storage unit 9 is a storage device such as a semiconductor memory element for storing programs, information, and the like necessary for the operation of the camera 1.
The storage unit 9 stores information on the upper limit temperature of use of the electronic components of the camera 1. In the present embodiment, the image sensor 3, the image processing unit 4, the rechargeable battery 5, and the OB unit of the image sensor 3. Is stored.
Further, the storage unit 9 includes information on the temperature rise with the passage of time after the power of the camera 1 of the image sensor 3, the image processor 4, the rechargeable battery 5, and the OB unit of the image sensor 3 is turned on, and the time after the power is shut off. Information on temperature decrease with the passage of time is recorded. Specifically, as shown in FIG. 3A, for example, in the storage unit 9, the temperature sensor of each unit with respect to an elapsed time t after the camera 1 is turned on in an environment where the outside temperature of the camera 1 is 20 ° C. A locus of temperature rise is recorded that includes temperature data T of 31, 41, 51 and temperature data T (described later) of the OB portion detected by calculation from the OB output of the image sensor 3.

Similarly, in the storage unit 9, the temperature data T of the temperature sensors 31, 41, 51 of each part of the camera 1 measured with respect to the elapsed time t after the camera 1 is turned off, and the image sensor 3 The locus of the temperature drop composed of the temperature data T of the OB portion is recorded.
Further, as shown in FIG. 3B, the storage unit 9 includes a temperature rise slope a indicating a temperature change per unit time obtained from each of the above-described temperature rise and temperature fall trajectories, and a temperature drop. The inclination b is stored.
In the present embodiment, the storage unit 9 stores information on a temperature rise locus and information on a temperature drop locus in an environment of a plurality of different outside air temperatures (5 types of 10, 20, 30, 40, and 50 ° C.). In association with this, a temperature rise slope a and a temperature fall slope b are also recorded for each of the different ambient temperature environments (see FIG. 3B).

The control unit 10 is a control circuit that performs overall control of each unit of the camera 1 and includes, for example, a CPU. The control unit 10 is connected to the imaging device 3, the image processing unit 4, the rechargeable battery 5, the display unit 6, the operation unit 7, the shutter unit 8, the storage unit 9, and the like. Further, the control unit 10 inputs the OB output of the image sensor 3 detected by the image processing unit 4 and detects the temperature data T of the OB unit of the image sensor 3 based on the OB output.
The control unit 10 is based on the above-described temperature change information stored in the storage unit 9, the temperature data T of the temperature sensors 31, 41, 51 provided in each unit, the above-described temperature data T of the OB unit, and the like. The outside temperature of the camera 1 is predicted. And the control part 10 is based on the estimated outside temperature, the information of the temperature change memorize | stored in the memory | storage part 9, the information of use upper limit temperature, and each temperature data T, and each part (imaging element 3,. The remaining prediction time that can be used by the image processing unit 4 and the rechargeable battery 5) is calculated.

Next, calculation of the outside air temperature when the camera 1 is turned off will be described.
FIG. 4 is a flowchart for explaining the outside air temperature calculation process when the camera 1 of the present embodiment is powered off.
When the power is cut off from the power-on state of the camera 1, as shown in FIG. 4, in step (hereinafter referred to as “S”) 101, the control unit 10 takes the temperature sensors 31, 41, 51 of each part of the camera 1 and the imaging. The temperature data T1 of the OB portion of the element 3 is detected.
In S102, the control unit 10 waits for a certain time (for example, 5 minutes) to elapse, and in S103, the control unit 10 detects the temperature sensors 31, 41, 51 of each unit of the camera 1 and the OB unit of the image sensor 3. Each temperature data T2 is detected.
In S104, the control unit 10 refers to each temperature data to determine whether each unit (the image sensor 3, the image processing unit 4, the rechargeable battery 5, and the OB unit of the image sensor 3) is radiating heat. Here, the determination of whether or not heat is dissipated is performed based on the detected temperature data T1 and T2 and the elapsed time t1 from the detection of the temperature data T1 to the detection of the temperature data T2.

  Specifically, in the case of the image sensor 3, the control unit 10 detects the temperature data T2 detected by the temperature sensor 31 in S103, the temperature data T1 detected by the temperature sensor 31 in S101, and the detection of the temperature data T1. Based on the elapsed time t1 until the detection of the temperature data T2, the inclination b (b = (T2-T1) / t1) of the temperature decrease of the image sensor 3 after the power supply of the camera 1 is cut off. Then, the control unit 10 refers to the temperature decrease inclination information (see FIG. 3B) recorded in the storage unit 9 and based on the calculated temperature decrease inclination b, the outside of the camera 1. Find the temperature To. For example, when the calculated slope b of the temperature decrease matches or approximates b2, the control unit 10 determines that the outside air temperature To based on the image sensor 3 is 20 ° C.

  Then, the control unit 10 compares the obtained outside air temperature To with the temperature data T2 detected in S103, and determines whether or not the image sensor 3 is sufficiently dissipating heat. Here, the determination of whether or not heat is released is determined by whether or not the absolute value of the difference between T2 and To is below a predetermined temperature (for example, 2 ° C.), and the absolute value of the difference between T2 and To is When it is 2 degrees C or less, the control part 10 determines with the image pick-up element 3 fully radiating heat | fever. On the other hand, when the absolute value of the difference between T2 and To is not 2 ° C. or less, it is determined that the image sensor 3 is not radiating heat. The control unit 10 performs the same determination on the image processing unit 4, the rechargeable battery 5, and the OB unit of the image sensor 3.

If it is determined by the above determination that all the parts of the camera 1 are sufficiently dissipated (S104, Yes), the process proceeds to S105. On the other hand, when it is determined that heat is not sufficiently dissipated even at one place among the respective parts of the camera 1 (S104, No), the process proceeds to S106.
In S <b> 105, the control unit 10 sets each detected temperature data T <b> 2 as outside air temperature data of each unit of the camera 1.
In S <b> 106, the control unit 10 detects the electronic component that is determined not to be dissipated based on the temperature data and the temperature change information stored in the storage unit 9 (see FIG. 3B). Calculate the temperature. The temperature data T2 of the electronic component determined to be dissipated is directly used as the outside temperature data of the electronic component.

  For example, when the electronic component determined not to be dissipated is the image sensor 3, the control unit 10 detects the temperature data T2 detected in S103, the temperature data T1 of the temperature sensor 31 detected in S101, and the temperature data T1. On the basis of the elapsed time t1 from the detection of temperature data T2 to the detection of temperature data T2, the inclination b (b = (T2−T1) / t1) of the temperature drop of the image sensor 3 after the camera 1 is turned off is calculated. Then, the control unit 10 refers to the temperature decrease gradient information (see FIG. 3B) stored in the storage unit 9 and based on the calculated temperature decrease gradient b, the control unit 10 Find the temperature To. For example, when the calculated temperature decrease slope b matches or approximates b2, the control unit 10 determines that the outside air temperature To based on the image sensor 3 is 20 ° C., and determines this value outside the image sensor 3. Use temperature data.

In S <b> 107, the control unit 10 calculates each difference in the outside air temperature data of each part of the camera 1 and determines whether or not each difference is within 3 ° C.
When it is determined that each difference in outside air temperature data is within 3 ° C. (S107, Yes), the process proceeds to S108, and when it is determined that at least some of the differences in outside air temperature data are greater than 3 ° C. (S107, No), go to S116.

In S108, the control unit 10 determines that the temperature sensor 51 provided in the rechargeable battery 5 is normal because the outside air temperature data of each part of the camera 1 indicates a range within 3 ° C. In subsequent S109 to S114, the control unit 10 cuts off the power source of the image sensor 3, the image processing unit 4 and the like, and calculates the outside air temperature data based only on the temperature sensor 51 of the rechargeable battery 5. As a result, the control unit 10 does not activate the imaging device 3 or the image processing unit 4 that consumes a large amount of power for temperature detection, and the temperature sensor 51 of the rechargeable battery 5 that consumes less power consumes the camera 1 when the power is shut off. The outside air temperature can be calculated, and the power consumption of the camera 1 can be reduced.
In S109, the control unit 10 calculates the average value of the outside air temperature data of each part of the camera 1, and stores the average value in the storage unit 9 as the predicted outside air temperature of the camera 1 in S110.
Then, in S111, the control unit 10 waits for a certain time (for example, 1 minute) and increments the value of the counter C by 1.

In S112, the control unit 10 determines whether or not the value of the counter C has reached C = 1000. When it is determined that the value of the counter C has reached 1000 (S112, Yes), the process proceeds to S115, and when it is determined that the value has not reached (S112, No), the process proceeds to S113.
In S <b> 113, the control unit 10 detects only the temperature data of the temperature sensor 51 provided in the rechargeable battery 5 and stores the detected temperature data in the storage unit 9 as the predicted outside air temperature of the camera 1.
In S114, the control unit 10 determines whether or not the camera 1 is turned on. If it is determined that the power is turned on (S114, Yes), the control unit 10 proceeds to S120 and determines that the power is not turned on. If so (S114, No), the process returns to S111.
On the other hand, when it is determined that the value of the counter C has reached C = 1000 (S112, Yes), in S115, the control unit 10 resets the value of the counter C, that is, sets C = 0, and proceeds to S119.

When it is determined in S107 that the difference between at least some of the outside air temperature data is greater than 3 ° C. (S107, No), in S116, the control unit 10 determines the average value of the outside air temperature data in which each difference is within 3 ° C. Is calculated. In S117, the calculated average value is stored in the storage unit 9 as the predicted outside air temperature, and in S118, it waits for a certain time (for example, 10 minutes) to elapse.
In S119, the control unit 10 determines whether or not the power of the camera 1 is turned on. If it is determined that the power is turned on (S119, Yes), the process proceeds to S120, and the power is not turned on. (S119, No), it returns to S103.
In S120, the control unit 10 ends the calculation of the outside air temperature.
With the above operation, the camera 1 can accurately calculate the predicted outside temperature of the camera 1 while the power is shut off.

Next, calculation of outside air temperature data after the camera 1 is turned on will be described.
FIG. 5 is a flowchart for explaining the operation of the camera 1 after the power is turned on according to this embodiment.
When the power of the camera 1 is turned on by a power switch (not shown), as shown in FIG. 5, in S201, the control unit 10 controls the temperature sensors 31, 41, 51 and OB of the image sensor 3 immediately after the power is turned on. Temperature data T3 is detected.
In S202, the control unit 10 waits for a certain time (for example, 3 minutes) to elapse, and then again in S203, the temperature sensors 31, 41, and 51 of each unit and the temperature of the OB unit of the image sensor 3 are again measured. Data T4 is detected.
Then, in S204, the control unit 10 calculates the outside air temperature of each part of the camera 1 based on the detected temperature data T3 and T4 and the elapsed time t2 from the detection of the temperature data T3 to the detection of the temperature data T4. .

Specifically, in the case of the image sensor 3, the control unit 10 performs the temperature data T4 detected in S203, the temperature data T3 immediately after power-on detected in S201, and the detection of the temperature data T3 to the detection of the temperature data T4. The temperature information gradient a (a = (T4-T3) / t2) is calculated based on the elapsed time t2. Then, the control unit 10 refers to the temperature rise inclination information (see FIG. 3B) stored in the storage unit 9 and based on the calculated temperature rise inclination a, the outside of the camera 1. Obtain temperature data. For example, when the calculated slope a of temperature increase coincides with or approximates a2, the control unit 10 determines that the outside air temperature data based on the image sensor 3 is 20 ° C.
Similarly, the control unit 10 also obtains the outside air temperature data based on the image processing unit 4, the rechargeable battery 5, and the OB unit of the image sensor 3.

Next, in S <b> 205, the control unit 10 calculates each difference in the outside air temperature data of each part of the camera 1 and determines whether or not the difference is within 3 ° C.
When it is determined that all the differences in outside air temperature data are within 3 ° C. (S205, Yes), the process proceeds to S206, and when it is determined that at least some of the differences in outside air temperature data are not within 3 ° C. (S205). , No), the process proceeds to S207.
In S206, since the outside air temperature data of each part of the camera 1 are all within 3 ° C., the control unit 10 calculates the average value of all the outside air temperature data of each part of the camera 1 and calculates the average value of the camera 1. It memorize | stores in the memory | storage part 9 as estimated outside temperature.
In S207, the control unit 10 calculates an average value of only the outside air temperature data in which each difference is within 3 ° C., and stores the average value in the storage unit 9 as the predicted outside air temperature.
In S <b> 208, the control unit 10 calculates the remaining predicted time tp until the use upper limit temperature of each unit (the image sensor 3, the image processing unit 4, and the rechargeable battery 5) of the camera 1 is reached. The predicted time tp is calculated by the following equation.
tp = (Tp−T4) / a

  Here, tp is the remaining predicted time until the upper limit temperature of use of each part of the camera 1 is reached, and T4 from each temperature sensor 31, 41, 51 and the OB part of the image sensor 3 in S203 as described above. It is the detected measurement data, Tp is the upper limit use temperature of each part of the camera 1 stored in the storage unit 9, and a is the temperature rise of each part of the camera 1 in the environment of the predicted outside air temperature over time It is a slope.

For example, when the predicted outside air temperature of the camera 1 is 20 ° C., the control unit 10 stores, from the storage unit 9, information on the temperature rise gradient indicating the temperature change per unit time of the outside air temperature 20 ° C. (FIG. 3B). Are read from each of the image sensor 3, the image processing unit 4, the rechargeable battery 5, and the OB unit of the image sensor 3. In this case, the read inclination of each part is a2 for the image sensor 3, a12 for the image processor 4, a22 for the rechargeable battery 5, and a32 for the OB part of the image sensor 3.
At this time, the upper limit temperature of use of the image sensor 3 is Tp = 60 ° C., the inclination of the temperature rise of the image sensor 3 is a2 = 0.2, and the temperature data detected from the temperature sensor 31 in S203 is T4 = 40. When it is assumed that it is ° C., the remaining predicted time tp reaching the use upper limit temperature Tp of the image sensor 3 is calculated as 100 minutes by the above formula. Similarly, the control unit 10 calculates each remaining predicted time tp until the use upper limit temperature is reached for the image processing unit 4, the rechargeable battery 5, and the OB unit of the image sensor 3.
In addition, since the temperature of the rechargeable battery 5 rises very quickly when abnormal heat generation occurs, the power supply of the camera 1 is often shut off immediately, so the remaining prediction until the upper limit temperature of the rechargeable battery 5 is reached is predicted. The time calculation may be omitted.

  In step S <b> 209, the control unit 10 determines whether there is a predicted time tp that is equal to or shorter than a predetermined time (for example, 5 minutes) among the predicted times tp of the respective units of the camera 1. When it is determined that at least one prediction time tp is 5 minutes or less among the prediction times tp (S209, Yes), the process proceeds to S210, and when any prediction time tp is determined not to be 5 minutes or less (S209, No) ), Go to S212.

In S210, the control unit 10 determines whether or not the prediction time tp of 5 minutes or less includes the prediction time tp = 0 minutes. When it is determined that the predicted time of tp = 0 minutes is included (S210, Yes), the process proceeds to S213. When it is determined that the predicted time is not included (S210, No), the process proceeds to S211.
In S211, the control unit 10 displays the electronic component name and the predicted time tp on the display unit 6 for the electronic component that indicates the shortest predicted time tp among the predicted times tp of 5 minutes or less. For example, when the electronic component showing the shortest predicted time tp (= 2 minutes) is the image processing unit 4, the display unit 6 displays “The temperature of the image processing unit is rising. A warning message such as “Power is cut off” is displayed. Thus, the photographer can recognize in advance when the power of the camera 1 is cut off, and can recognize which part of the camera 1 is generating heat.
In S212, the control unit 10 returns to S203 after a predetermined time (for example, 1 minute) has elapsed, and repeats the operations after S203.

  When it is determined in S210 that one of the predicted times tp is 0 minutes among the units of the camera 1 (S210, Yes), the control unit 10 shuts off the power of the camera 1 in S213. Thereby, the camera 1 can avoid driving beyond the usable time of each electronic component, and can prevent the camera 1 from being damaged by heat generation.

As described above, the camera 1 of the present embodiment has the following effects.
(1) The control unit 10 includes temperature data of the temperature sensors 31, 41, 51 of the respective units (the image sensor 3, the image processing unit 4, and the rechargeable battery 5) of the camera 1 and the OB unit of the image sensor 3, and the upper limit of use of each unit. Based on the temperature information, the remaining estimated time available for each part of the camera 1 is calculated. Thereby, the photographer can be made aware of the time until the power of the camera 1 is shut off, and the power of the camera 1 can be prevented from being shut off suddenly. Moreover, since the existing temperature sensor etc. are used for the camera 1, it is not necessary to provide a temperature sensor anew in a camera, and it can avoid that the manufacturing cost of the camera 1 increases.

(2) The control unit 10 calculates the predicted outside air temperature of the camera 1 based on the temperature data of the temperature sensors 31, 41, 51 and the OB part of the image sensor 3, and uses the calculated predicted outside air temperature and temperature data. Based on the information on the upper limit temperature, the remaining usable prediction time of each part of the camera 1 is calculated, so that a more accurate prediction time can be obtained.
(3) The camera 1 stores the inclination information of the temperature change per unit time of each electronic component for different outside air temperatures in the storage unit 9, and the control unit 10 determines the outside air temperature based on the inclination information and the temperature data. Since the data is obtained, the predicted outside temperature can be calculated more specifically.

(4) Since the control unit 10 can acquire temperature data from a plurality of electronic components (the image sensor 3, the image processing unit 4, and the rechargeable battery 5) and can calculate the outside air temperature data related to each electronic component, more An accurate predicted outside air temperature can be calculated, and the remaining estimated time available for each electronic component can be calculated.
(5) Since the controller 10 calculates the average value of the outside air temperature data by excluding the outside air temperature data with low reliability from the calculated outside air temperature, the temperature data of one electronic component is an abnormal value. Even so, it is possible to obtain an accurate predicted outside temperature by excluding it, and to calculate an accurate usable time.

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications and changes can be made as in the modifications described later, and these are also included in the present invention. Within the technical scope. In addition, the effects described in the embodiments are merely a list of the most preferable effects resulting from the present invention, and the effects of the present invention are not limited to those described in the embodiments. It should be noted that the above-described embodiment and modifications described later can be used in appropriate combination, but detailed description thereof is omitted.

(Deformation)
(1) In the embodiment, an example in which four types of electronic components of the imaging device 3, the image processing unit 4, the rechargeable battery 5, and the OB portion of the imaging device 3 are used as electronic components for acquiring temperature data has been shown. However, it is possible to use other electronic components (for example, a display unit) mounted on the camera 1. Further, the number of electronic components for acquiring temperature data is not limited to four types, and one or more types, three or less types, or five or more types of electronic components can be used.
(2) In the embodiment, the control unit 10 displays the electronic component name and the predicted time tp for the electronic component that indicates the shortest predicted time tp among the predicted times tp that are equal to or shorter than a predetermined time (5 minutes). Although the example displayed on the part 6 was shown, it is not limited to this. For example, you may make it display on the display part all the electronic component names and prediction time tp of prediction time tp below predetermined time.

1: camera, 3: imaging device, 4: image processing unit, 5: rechargeable battery, 9: storage unit, 10: control unit, 31: temperature sensor, 41: temperature sensor, 51: temperature sensor

Claims (4)

An imaging device equipped with electronic components,
A temperature detector for detecting the temperature of the electronic component;
A storage unit storing information on the upper limit temperature of use of the electronic component;
Based on the temperature detection information of the temperature detection unit, the outside temperature of the imaging device is calculated, and based on the calculated information on the outside temperature, the temperature detection information, and the information on the upper limit temperature of use, A control unit for calculating the remaining usable time;
An imaging device comprising: The imaging device according to claim 1,
The storage unit stores temperature change information indicating a temperature change per unit time of the electronic component with respect to an outside air temperature of the imaging device,
The controller calculates the outside air temperature based on the temperature change information and the temperature detection information;
An imaging device characterized by the above. The imaging device according to claim 2,
The temperature detection unit is provided in each of the plurality of electronic components of the imaging device,
The controller is
Calculating the outside air temperature related to each of the temperature detectors,
Calculate the average value of the calculated outside air temperature,
Calculating the usable time of each electronic component based on the calculated average value, each temperature detection information of the temperature detection unit, and information on each use upper limit temperature of the electronic component;
An imaging device characterized by the above. In the imaging device according to claim 3,
The control unit calculates the average value of the outside air temperature by excluding the outside air temperature with low reliability out of the calculated outside air temperature,
An imaging device characterized by the above.

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