JP2020144243A - Image processing device and program - Google Patents

Abstract

To realize control that conforms to a control condition stipulated for each operation mode of image processing as part of an effort to exercise control so that the total power consumption of modules used for image processing does not exceed a permissible amount.SOLUTION: A power consumption information storage unit 20 stores power consumption information in which the power consumption of multiple modules is indicated for each module. A power consumption derivation unit 30 derives the total power consumption of one or more modules used in each operation mode of image processing by an image processing unit 10 from the power consumption per module that is indicated in the power consumption information. A control unit 40 controls the operation of modules used in each operation mode of image processing in accordance with the control condition of modules stipulated for each operation mode so that the total power consumption derived by the power consumption derivation unit 30 does not exceed a predetermined permissible amount.SELECTED DRAWING: Figure 1

Description

The present invention relates to an image processing apparatus and a program.

Patent Document 1 describes a temperature sensor that can detect a temperature and determine whether or not the detection result exceeds a reference value for each reference value and output the temperature sensor, and an operation of a calculation block based on an output signal of the temperature sensor. A semiconductor integrated circuit provided with a controllable control block is described. In Patent Document 1, the control block returns from the hibernation state to the operating state by an interrupt signal based on the output signal of the temperature sensor, and determines the operating conditions of the calculation block so as to satisfy the temperature condition of the calculation block.

Further, Patent Document 2 describes a semiconductor device having a plurality of functional units connected to each other by an internal bus. The semiconductor device of Patent Document 2 includes an operation mode output means for outputting a request for changing from an operation mode during operation to another operation mode according to the data processing content, and a functional unit for executing processing in a plurality of functional units. Power processing that controls the frequency and bus occupancy time of the clock signal used by the functional unit that executes the processing in response to a request to change the operation mode so that the total power consumption of the above does not exceed the limit power consumption given to the semiconductor device. It is equipped with speed control means.

Japanese Unexamined Patent Publication No. 2008-124125 International Publication No. 01/001228 Pamphlet

While the techniques described in Patent Documents 1 and 2 are known, devices having a plurality of operation modes related to image processing are also known. For example, a function that allows the user to select a desired operation mode from a plurality of operation modes such as a high-speed mode that realizes high-speed image processing and a high-quality mode that realizes high image quality of image contents is realized. There is.

In a device having a plurality of operation modes related to image processing, the content of processing to be prioritized may differ depending on the operation mode. For example, in a high-speed mode that realizes high-speed image processing, it is desirable to prioritize high-speed image processing rather than high-quality image content. On the other hand, for example, in a high image quality mode that realizes high image quality of image contents, it is desirable to prioritize high image quality of image contents rather than speeding up image processing.

As described above, the content of the processing to be prioritized may differ depending on the operation mode of the image processing. Therefore, for example, in controlling the power consumption of image processing, control is expected based on the fact that conditions such as processing that should be prioritized may differ depending on the operation mode of image processing.

An object of the present invention is to realize control according to control conditions determined for each operation mode of image processing in controlling the total power consumption of the module used for image processing so as not to exceed the permissible amount. is there.

The invention according to claim 1 is an image processing unit that executes image processing using one or more modules among a plurality of modules used in each operation mode of image processing, and the power consumption of the plurality of modules for each module. From the storage unit that stores the power consumption information shown in (1) and the power consumption of each module shown in the power consumption information, the total power consumption of one or more modules used in each operation mode of image processing by the image processing unit. And each operation mode of image processing according to the control conditions of the module defined for each operation mode so that the total power consumption derived by the derivation unit does not exceed a predetermined allowable amount. It is an image processing apparatus characterized by having a control unit for controlling the operation of the module used in the above.

The invention according to claim 2 is the image processing apparatus according to claim 1, wherein the control unit operates when the total power consumption of each operation mode derived by the derivation unit exceeds the allowable amount. The image processing apparatus is characterized in that the operation of at least one module used in the operation mode is stopped according to the control conditions corresponding to the mode.

According to the third aspect of the present invention, in the image processing apparatus according to the first or second aspect, the control unit controls the control unit when the total power consumption of each operation mode derived by the derivation unit exceeds the allowable amount. The image processing apparatus is characterized in that at least one module used in the operation mode is changed to a low power module having a power consumption smaller than that of the module according to the control conditions corresponding to the operation mode.

According to the invention of claim 4, in the image processing apparatus according to any one of claims 1 to 3, the control unit has the allowable amount of the total power consumption of each operation mode derived by the derivation unit. When the above is exceeded, at least a part of the parallel modules executed in parallel in the operation mode is changed to the execution by time division according to the control condition corresponding to the operation mode. It is a device.

The invention according to claim 5 is based on the power consumption information in the image processing apparatus according to any one of claims 1 to 4, depending on the manufacturing variation of the integrated circuit having the image processing function. The power consumption of each of the indicated modules is corrected, and the derivation unit is an image processing device that derives the total power consumption based on the corrected power consumption information.

The invention according to claim 6 is an integrated circuit having an image processing function and a voltage control for controlling a voltage applied to the integrated circuit in the image processing apparatus according to any one of claims 1 to 5. The integrated circuit further includes a circuit, the integrated circuit outputs internal voltage information indicating a voltage in the integrated circuit, and the voltage control circuit outputs the integrated voltage information based on the internal voltage information output from the integrated circuit. It is an image processing device characterized by controlling the magnitude of a voltage applied to a circuit.

According to the invention of claim 7, in the image processing apparatus according to claim 6, the internal voltage information includes information indicating a voltage corresponding to the present time in the integrated circuit and the voltage in the integrated circuit at the present time. It is an image processing apparatus characterized in that it contains information indicating that the voltage changes from the corresponding voltage.

The invention according to claim 8 is a storage means for storing power consumption information indicating the power consumption of a plurality of modules used in each operation mode of image processing for each module, and each module shown in the power consumption information. The derivation means for deriving the total power consumption of one or more modules used in each operation mode of image processing from the power consumption of the above, and the total power consumption derived by the derivation means does not exceed a predetermined allowable amount. As described above, it is a program that functions as a control means for controlling the operation of the module used in each operation mode of image processing according to the control conditions of the module determined for each operation mode.

According to the invention of claim 1, in controlling the total power consumption of the module used for image processing so as not to exceed the permissible amount, control according to the control conditions determined for each operation mode of image processing is realized. To.

According to the second aspect of the present invention, when the total power consumption of each operation mode exceeds the permissible amount, control for stopping the operation of at least one module according to the control conditions corresponding to the operation mode is realized.

According to the invention of claim 3, when the total power consumption of each operation mode exceeds the permissible amount, control of changing at least one module to a low power module according to the control conditions corresponding to the operation mode is realized.

According to the invention of claim 4, when the total power consumption of each operation mode exceeds the permissible amount, control is realized in which at least some of the parallel modules are changed to time-division execution according to the control conditions corresponding to the operation mode. Ru.

According to the invention of claim 5, in controlling the total power consumption of the module used for image processing so as not to exceed the permissible amount, the correction according to the manufacturing variation of the integrated circuit having the image processing function is performed. The accompanying control is realized.

According to the sixth aspect of the present invention, the magnitude of the voltage applied to the integrated circuit can be controlled based on the internal voltage information indicating the voltage in the integrated circuit having the image processing function.

According to the invention of claim 7, the magnitude of the voltage applied to the integrated circuit can be controlled based on the fact that the voltage in the integrated circuit having the image processing function changes from the voltage corresponding to the present time. ..

According to the invention of claim 8, a program for controlling the total power consumption of the module used for the image processing so as not to exceed the permissible amount is provided according to the control conditions determined for each operation mode of the image processing.

It is a figure which shows the specific example of an image processing apparatus. It is a figure which shows the specific example of the power consumption table. It is a figure which shows the specific example of the constraint condition defined for each operation mode. It is a figure which shows the specific example of the invalidation priority. It is a figure which shows the specific example of the change to a low power module. It is a figure which shows the specific example of the change from parallel processing to time division processing. It is a figure which shows the specific example of the operation which an image processing apparatus performs. It is a figure which shows the specific example of the power consumption suppression processing. It is a figure for demonstrating the manufacturing variation of an integrated circuit.

FIG. 1 is a diagram showing an example of a specific embodiment of the present invention. FIG. 1 shows a specific example of the image processing device 100. The image processing device 100 illustrated in FIG. 1 includes an image processing unit 10, a power consumption information storage unit 20, a power consumption derivation unit 30, and a control unit 40.

The image processing unit 10 executes image processing by using one or more of the plurality of modules used in each operation mode of image processing.

The power consumption information storage unit 20 stores power consumption information indicating the power consumption of a plurality of modules for each module. The power consumption information storage unit 20 may be realized by using a storage device such as a semiconductor memory. Of course, the power consumption information storage unit 20 may be realized by using a storage device other than the semiconductor memory.

The power consumption derivation unit 30 derives the total power consumption of one or more modules used in each operation mode of image processing by the image processing unit 10 from the power consumption of each module shown in the power consumption information.

The control unit 40 performs in each operation mode of image processing according to the control conditions of the module determined for each operation mode so that the total power consumption derived by the power consumption extraction unit 30 does not exceed a predetermined allowable amount. Controls the behavior of the modules used.

Further, as illustrated in FIG. 1, the image processing device 100 includes an image data output unit 50, a print processing unit 52, an image data acquisition unit 60, an image reading unit 62, a voltage information output unit 70, an integrated circuit 80, and a voltage. A control circuit 90 may be provided.

The image data output unit 50 outputs image data, and the print processing unit 52 prints an image (including an image containing only characters and symbols) corresponding to the image data. For example, even if the image data processed by the image processing unit 10 is output from the image data output unit 50, the image corresponding to the image data is printed on a medium such as paper, and output from the print processing unit 52. Good.

The image data acquisition unit 60 acquires image data from the image reading unit 62. The image reading unit 62 performs a scanning process for optically reading an image (including an image containing only characters and symbols) shown on a document such as paper to acquire image data of the image, and the image data acquisition unit 62. 60 may acquire the image data from the image reading unit 62, and the image processing unit 10 may execute image processing on the image data.

The integrated circuit 80 has an image processing function. For example, as illustrated in FIG. 1, an image processing unit 10, a power consumption information storage unit 20, a power consumption derivation unit 30, a control unit 40, an image data output unit 50, and an image data acquisition unit 60 are included in the integrated circuit 80. A voltage information output unit 70 or the like may be formed.

As the integrated circuit 80, a device such as an ASIC (Application Specific Integrated Circuit) may be used. Of course, a device other than the ASIC may be used as the integrated circuit 80.

The voltage information output unit 70 outputs internal voltage information indicating the voltage in the integrated circuit 80. Further, the voltage control circuit 90 controls the magnitude of the voltage applied to the integrated circuit 80 based on the internal voltage information output from the voltage information output unit 70 in the integrated circuit 80.

The internal voltage information output from the integrated circuit 80 includes, for example, information indicating the voltage corresponding to the current time in the integrated circuit 80 and information indicating that the voltage in the integrated circuit 80 changes from the voltage corresponding to the current time. It may be included.

If the internal voltage information includes information indicating the current voltage in the integrated circuit 80, the voltage control circuit 90 is the difference between the current voltage in the integrated circuit 80 and the predetermined target voltage. The magnitude of the voltage applied to the integrated circuit 80 may be controlled by the feedback control using the above.

Further, if the internal voltage information includes information indicating that the voltage in the integrated circuit 80 changes from the voltage corresponding to the present time, the voltage control circuit 90 has the voltage in which the voltage in the integrated circuit 80 corresponds to the present time. Control may be performed based on the change from. For example, even if the voltage applied to the integrated circuit 80 is shifted higher before the operation with a high power load is started in the integrated circuit 80, and the voltage is restored just before the end of the operation. Good. Further, for example, when information indicating that the electric power load in the integrated circuit 80 continues to be low is obtained, the voltage control circuit 90 applies the minimum voltage that guarantees the operation of the integrated circuit 80 to the integrated circuit 80. You may do so.

Further, the image processing apparatus 100 is a module operating in the integrated circuit 80, for example, when the voltage applied to the integrated circuit 80 is likely to fall below a predetermined lower limit value (for example, minus several percent from the target voltage). At least a part of the above may be temporarily stopped, or when the voltage applied to the integrated circuit 80 is likely to exceed a predetermined upper limit value (for example, plus a few percent from the target voltage), the inside of the integrated circuit 80 At least a part of the modules stopped at may be temporarily operated.

The image processing device 100 illustrated in FIG. 1 may be realized by using, for example, one or more computers. The computer is a computing device such as a CPU, a storage device such as a memory or a hard disk, a communication device using a communication line such as the Internet, a device that reads data from a storage medium such as an optical disk, a semiconductor memory, or a card memory, and a display. It is equipped with hardware resources such as display devices such as, and operation devices that accept operations from users.

Then, for example, a program (software) corresponding to at least a part of the functions of the coded plurality of parts of the image processing apparatus 100 illustrated in FIG. 1 is read into the computer, and the hardware resources of the computer are used. In cooperation with the loaded software, at least a part of the functions of the image processing apparatus 100 illustrated in FIG. 1 may be realized by a computer. The program may be provided to a computer (image processing device 100) via a communication line such as the Internet, or may be stored in a storage medium such as an optical disk, a semiconductor memory, or a card memory and stored in the computer (image processing device 100). ) May be provided.

Further, the image processing apparatus 100 illustrated in FIG. 1 is a composite type apparatus having a plurality of image output functions (at least some functions such as a printing function, a scanner function, a copying function, and a facsimile function). May be good. For example, if the image processing device 100 of FIG. 1 is a composite device, it may be installed in a company or school and used by customers of the company or school, or it may not be installed in a store such as a convenience store. It may be used by a specific number of customers.

The overall configuration of the image processing apparatus 100 illustrated in FIG. 1 is as described above. Next, specific examples of processing and the like realized by the image processing apparatus 100 of FIG. 1 will be described in detail. Regarding the configuration (part) shown in FIG. 1, the reference numerals in FIG. 1 are used in the following description.

FIG. 2 is a diagram showing a specific example of the power consumption table. The power consumption table illustrated in FIG. 2 is one of specific examples of power consumption information showing the power consumption of a plurality of modules for each module. FIG. 2 illustrates a power consumption table showing the power consumption of a plurality of modules from module numbers 0 to N (N is a natural number) for each module.

In the power consumption table illustrated in FIG. 2, for example, the power consumption of the module whose module name is AD conversion (analog-to-digital conversion) is P ₀ [W (watt)], and the module name is module number 1. The power consumption of a module of an image standard (for example, a standard related to an image such as PEG) is P ₁ [W (watt)].

The power consumption table illustrated in FIG. 2 is stored in, for example, the power consumption information storage unit 20, and is used by the power consumption derivation unit 30 for deriving the total power consumption. For example, among the plurality of modules of module numbers 0 to N illustrated in the power consumption table of FIG. 2, a plurality of modules of module numbers 0 to 6 are used in the scan process, and module numbers 2 to 9 are used in the copy process. A plurality of modules may be used, and a plurality of modules from module numbers 10 to N may be used in the printing process.

If a plurality of modules from module numbers 0 to 6 are used in the scan process, the power consumption derivation unit 30 consumes the power consumption of FIG. 2 when executing the image process related to the scan process in each operation mode described in detail later. The total power consumption is derived by adding up the power consumptions of the plurality of modules of module numbers 0 to 6 exemplified in the power table.

Further, if a plurality of modules of module numbers 2 to 9 are used in the copy processing, the power consumption derivation unit 30 may use the power consumption table of FIG. 2 when executing the image processing related to the copy processing in each operation mode. The total power consumption is derived by adding up the power consumptions of the plurality of modules of the module numbers 2 to 9 illustrated in 1.

Further, if a plurality of modules from module numbers 10 to N are used in the print processing, the power consumption derivation unit 30 may use the power consumption table of FIG. 2 when executing the image processing related to the print process in each operation mode. The total power consumption is derived by adding up the power consumptions of the plurality of modules from module numbers 10 to N exemplified in 1.

The control unit 40 performs in each operation mode of image processing according to the control conditions of the module determined for each operation mode so that the total power consumption derived by the power consumption extraction unit 30 does not exceed a predetermined allowable amount. Controls the behavior of the modules used.

FIG. 3 is a diagram showing a specific example of the constraint conditions defined for each operation mode. The constraint condition illustrated in FIG. 3 is one of specific examples relating to the control condition of the module defined for each operation mode. FIG. 3 illustrates a high-speed mode, a normal mode, a photographic mode, and a high-quality mode as specific examples of the operation mode.

In the specific example shown in FIG. 3, the constraint condition of the high-speed mode is given priority to high-speed. Therefore, when the operation mode is the high-speed mode and the total power consumption exceeds the permissible amount, the operation of the module is controlled with priority given to speeding up the image processing. For example, at least one module that was intended to be used in high speed mode may be deactivated according to the disabling priority that defines the priority of the modules that may be disabled.

Further, in the specific example shown in FIG. 3, the constraint condition of the normal mode is to maintain the processing speed. Therefore, when the operation mode is the normal mode and the total power consumption exceeds the permissible amount, the operation of the module is controlled so that the speed of image processing is maintained as much as possible. For example, at least one module that was planned to be used in normal mode is changed to a low power module that consumes less power than that module. For example, it may be changed to a module having a lower resolution than the module to be used.

Further, in the specific example shown in FIG. 3, the constraint condition of the photo mode is to maintain the photo function. Therefore, when the operation mode is the photo mode and the total power consumption exceeds the permissible amount, the operation of the module is controlled so that the function of the photo is maintained as much as possible. For example, the operation of at least one module that was intended to be used in photographic mode is stopped. For example, the module related to the color and monochrome determination function may be stopped, and all the images to be processed may be treated as color. When the image to be processed is monochrome, for example, by process black (PK) generated from four color components of cyan (C), magenta (M), yellow (Y), and black (K). , Monochrome images may be formed.

Further, in the specific example shown in FIG. 3, the constraint condition of the high image quality mode is given priority to high image quality. Therefore, when the operation mode is the high image quality mode and the total power consumption exceeds the permissible amount, the operation of the module is controlled so that the image quality of the image to be processed is maintained as high as possible. For example, at least a portion of the parallel modules that were planned to be executed in parallel in high quality mode may be changed to time division execution.

FIG. 4 is a diagram showing a specific example of the invalidation priority. FIG. 4 shows a specific example of the invalidation priority that defines the priority of the modules that may be invalidated.

If the operation of the module that was planned to be used for image processing is stopped, the power consumption may be reduced more than planned, but the image quality may deteriorate. In this case, there is a trade-off between power reduction and image quality deterioration.

Therefore, for example, the degree of the trade-off may be confirmed in advance (for example, at the design stage of the image processing apparatus 100), and the invalidation priority may be determined based on the confirmation result. For example, a module with less deterioration in image quality and greater power reduction may have a higher invalidation priority and closer to the highest priority "1".

FIG. 4 illustrates the degree of image quality and the degree of power for each module from module M0 to module M7. In the specific example shown in FIG. 4, for example, the module M3 having the least deterioration in image quality and the second largest power consumption reduction effect even when disabled from the normal state before invalidation has the highest priority "1". The invalidation priority may be determined in the order of module M3 to module M7, module M0, module M1, module M6, and module M2.

Modules whose image quality deteriorates too much may be excluded from the invalidation priority. For example, in the specific example shown in FIG. 4, the modules M4 and the module M5 whose image quality is worse than the low image quality threshold Th may be excluded from the invalidation priority so that the operation is not stopped.

FIG. 5 is a diagram showing a specific example of the change to the low power module. FIG. 5 shows specific examples before and after the change to the low power module for image processing including the image processing group A, the image processing group B, the image processing group C, and two scaling processes. In the specific example shown in FIG. 5, for example, image processing is performed in the order of image processing group A, scaling processing, image processing group B, scaling processing, and image processing group C.

In the image processing before the change illustrated in FIG. 5, low-resolution image processing is executed by the image processing group A, the low-resolution processing result is enlarged / reduced, and then the high-resolution image processing is performed by the image processing group B. Is executed, the high-resolution processing result is enlarged / reduced, and then the high-resolution image processing is executed by the image processing group C.

If the total power consumption exceeds the permissible amount in the image processing before the change, at least one module that was planned to be used before the change becomes a low power module that consumes less power than that module. Be changed. In the specific example shown in FIG. 5, one or more modules used as the image processing group B are changed to low-resolution low-power modules.

Therefore, in the modified image processing illustrated in FIG. 5, low-resolution image processing is executed by the image processing group A, the low-resolution processing result is enlarged / reduced, and then the image processing group B performs low-resolution image processing. After the image processing is executed and the low-resolution processing result is enlarged / reduced, the high-resolution image processing is executed by the image processing group C.

As a result, in the specific example shown in FIG. 5, the power consumed by the image processing group B after the change and the scaling processing executed thereafter is reduced as compared with the image processing before the change, and the image processing after the change is compared with that before the change. The total power consumption of the whole is also reduced.

Further, in the specific example shown in FIG. 5, the amount of data transferred between the image processing group B and the DDR (Double Data Rate) memory is reduced after the change as compared with before the change, and the latter stage of the image processing group B. Since the amount of data transferred between the enlargement / reduction processing and the DDR memory is also reduced, the processing speed of the entire image processing after the change is improved as compared with that before the change.

FIG. 6 is a diagram showing a specific example of the change from parallel processing to time division processing. FIG. 6 illustrates a specific example of image processing by parallel processing before the change and a specific example of image processing by time division processing after the change. In the specific example shown in FIG. 6, image processing proceeds in the order of processing 1 (1a, 1b), image processing group A, processing 2 (2a, 2b), image processing group B, and processing 3 (3a, 3b).

In the image processing before the change illustrated in FIG. 6, processing 1a and processing 1b are processed in parallel, then processing by the image processing group A is executed, then processing 2a and processing 2b are processed in parallel, and then image processing. After the processing by the group B is executed, the processing 3a and the processing 3b are processed in parallel.

In the image processing before the change illustrated in FIG. 6, for example, one or more modules corresponding to the processing 1a and one or more modules corresponding to the processing 1b are executed in parallel, and the one or more modules corresponding to the processing 2a and one or more modules are executed in parallel. One or more modules corresponding to the process 2b are executed in parallel, and one or more modules corresponding to the process 3a and one or more modules corresponding to the process 3b are executed in parallel.

Then, when the total power consumption exceeds the permissible amount in the image processing before the change, at least a part of the parallel modules scheduled to be executed in parallel is changed to the execution by time division. In the specific example shown in FIG. 6, process 1a and process 1b are changed from parallel processing to time division processing, process 2a and process 2b are changed from parallel processing to time division processing, and process 3a and process 3b are changed from parallel processing to time division processing. It is changed to division processing.

As a result, in the specific example shown in FIG. 6, the total power consumption of the process 1a and the process 1b (for example, the power consumption per unit time) is reduced after the change as compared with the case before the change, and the process 2a and the process 2b The total power consumption (for example, the power consumption per unit time) is reduced, and the total power consumption of the processes 3a and 3b (for example, the power consumption per unit time) is reduced.

FIG. 7 is a diagram showing a specific example of the operation executed by the image processing device 100. When the image processing device 100 receives, for example, an instruction to start image processing, the image processing device 100 executes an operation according to the flowchart illustrated in FIG.

When the flowchart shown in FIG. 7 is started, the operation mode is first set (S701). The image processing device 100 receives an operation mode setting from the user via an operation device such as a touch panel. The operation mode may be set in advance (for example, initial setting) before the flowchart illustrated in FIG. 7 is started.

Next, the module to be used is specified (S702). For example, if the scan process is executed in the set operation mode, one or more modules used for the scan process (for example, a plurality of modules from module numbers 0 to 6 illustrated in FIG. 2) are specified. Further, when the copy process is executed, one or more modules used for the copy process (for example, a plurality of modules of module numbers 2 to 9 illustrated in FIG. 2) are specified. Further, when the printing process is executed, one or more modules used for the printing process (for example, a plurality of modules from module numbers 10 to N illustrated in FIG. 2) are specified.

When the module to be used is specified, the total power consumption is derived (S703). The power consumption derivation unit 30 was identified as a module to be used in S702 from the power consumption of each module shown in the power consumption information (for example, the power consumption table illustrated in FIG. 2) stored in the power consumption information storage unit 20. The total power consumption of one or more modules is derived.

Then, it is confirmed whether or not the derived total power consumption exceeds the permissible amount (S704). For example, the control unit 40 determines whether or not the total power consumption derived by the power consumption extraction unit 30 exceeds a predetermined amount. As the allowable amount, for example, a value set at the design stage of the image processing apparatus 100 may be used according to the specifications of the integrated circuit 80 and the like.

If the total power consumption exceeds the permissible amount in S704, the power consumption suppression process is executed (see S705 and FIG. 8). In the suppression process of S705, the operation of the module to be used specified in S702 is controlled. Then, the image processing unit 10 executes image processing according to the control (S706).

On the other hand, if the total power consumption does not exceed the permissible amount in S704, the image processing unit 10 executes image processing by using the planned use module specified in S702 as it is (S706). In this way, when the image processing is executed in S706, the flowchart of FIG. 7 ends.

FIG. 8 is a diagram showing a specific example of the power consumption suppression process. The image processing apparatus 100 executes an operation according to the flowchart illustrated in FIG. 8, for example, in the step S705 of FIG.

When the flowchart shown in FIG. 8 is started, the operation mode is first confirmed (S800). For example, the operation mode set in S701 of FIG. 7 is confirmed, and the processing according to the operation mode is executed in the operation after S800.

If the operation mode is the high-speed mode, for example, the operation of the module is stopped according to the invalidation priority (S811). As the invalidation priority, for example, the specific example illustrated in FIG. 4 may be used. For example, the control unit 40 stops the operation of the planned use modules specified in S702 of FIG. 7 in order from the one with the highest invalidation priority, that is, from the one with the priority closer to "1". To determine. Further, the power consumption derivation unit 30 derives the total power consumption of the remaining one or more modules excluding the invalid module. Then, it is confirmed whether or not the derived total power consumption exceeds the permissible amount (S812).

The processes of S811 and S812 are repeatedly executed until the total power consumption becomes equal to or less than the allowable amount. That is, the invalid modules are determined one after another according to the invalidation priority until the total power consumption of the remaining one or more modules excluding the invalid module becomes equal to or less than the allowable amount. When the total power consumption becomes less than the permissible amount, the flowchart shown in FIG. 8 ends, and the image processing unit 10 executes image processing using the remaining one or more modules excluding the invalid module (S706 in FIG. 7). ..

If the operation mode is the normal mode, for example, one or more modules are sequentially changed to low power modules (S821). The control unit 40 determines, for example, one after another a module to be changed from the planned use module specified in S702 of FIG. 7 to a low power module. For example, as in the specific example described with reference to FIG. 5, one or more modules used as the image processing group B are sequentially changed to low-resolution low-power modules. Further, the power consumption derivation unit 30 derives the total power consumption of the module after being changed to the low power module. Then, it is confirmed whether or not the derived total power consumption exceeds the permissible amount (S822).

The processes of S821 and S822 are repeatedly executed until the total power consumption becomes equal to or less than the allowable amount. That is, one or more modules are changed to low power modules one after another until the total power consumption of the modules after being changed to low power modules becomes less than the allowable amount. When the total power consumption becomes equal to or less than the permissible amount, the flowchart shown in FIG. 8 ends, and the image processing unit 10 executes image processing using one or more modules including the low power module (S706 in FIG. 7).

If the operation mode is the photographic mode, for example, the module related to the color and monochrome determination function is stopped (S831). For example, from the modules to be used specified in S702 of FIG. 7, one or more modules related to the color and monochrome determination function are stopped. Then, the flowchart shown in FIG. 8 is completed, and for example, the image processing unit 10 executes image processing by using one or more modules related to the photographic function that has not been stopped (S706 in FIG. 7).

If the operation mode is the high image quality mode, for example, a plurality of parallel modules are gradually changed to time division processing (S841). For example, the control unit 40 changes the parallel modules to be executed in parallel among the modules to be used specified in S702 of FIG. 7 to be executed by time division. For example, as in the specific example described with reference to FIG. 6, process 1a and process 1b are changed from parallel processing to time division processing, process 2a and process 2b are changed from parallel processing to time division processing, and process 3a. And process 3b is changed from parallel process to time division process.

Further, the power consumption derivation unit 30 derives the total power consumption of the module after the parallel processing is changed to the time division processing. Then, it is confirmed whether or not the derived total power consumption exceeds the permissible amount (S842).

The processes of S841 and S842 are repeatedly executed until the total power consumption becomes equal to or less than the allowable amount. For example, when four modules are scheduled to be executed in parallel, the time division is first divided into parallel processing of two modules and parallel processing of the remaining two modules. If the total power consumption exceeds the permissible amount in this time division, the parallel processing of the two modules is further changed to the time division processing, and the parallel processing of the remaining two modules is also changed to the time division processing. In this way, the time division processing may be changed step by step. Then, when the total power consumption becomes equal to or less than the allowable amount, the flowchart shown in FIG. 8 ends, and the image processing unit 10 executes image processing using one or more modules including the module executed in time division (FIG. FIG. 7 S706).

FIG. 9 is a diagram for explaining manufacturing variations of the integrated circuit 80. For example, when a semiconductor device such as an ASIC is used as the integrated circuit 80, the characteristics of each product of the integrated circuit 80 may differ due to variations in the manufacturing stage of the semiconductor device.

For example, as illustrated in FIG. 9, the standard product (TYPE product), which has the characteristics according to the design target or the average characteristic, has a higher operating power than the standard product (FAST product), and the standard product is selected. The characteristics of the integrated circuit 80 may vary from product to product in the range up to a product (SLOW product) whose operating power is smaller than that of the product. If the characteristics of the integrated circuit 80 vary from product to product, the power consumption of the same module may change from product to product of the integrated circuit 80.

Therefore, for example, the power consumption of each module shown in the power consumption information may be corrected according to the manufacturing variation of the integrated circuit 80. For example, the power consumption of each module shown in the power consumption table is corrected by multiplying the power consumption of the plurality of modules shown in the power consumption table illustrated in FIG. 2 by a coefficient corresponding to the variation of the integrated circuit 80. May be done. For example, at the design stage of the image processing device 100, a coefficient to be multiplied by the power consumption of the power consumption table may be determined according to the characteristics of the integrated circuit 80 used for manufacturing the image processing device 100.

Then, when the power consumption of the plurality of modules shown in the power consumption table is corrected, the power consumption derivation unit 30 derives the total power consumption based on the corrected power consumption table.

Although the preferred embodiments of the present invention have been described above, the above-described embodiments are merely examples in all respects, and do not limit the scope of the present invention. The present invention includes various modified forms without departing from its essence.

10 image processing unit, 20 power consumption information storage unit, 30 power consumption derivation unit, 40 control unit, 50 image data output unit, 52 print processing unit, 60 image data acquisition unit, 62 image reading unit, 70 voltage information output unit, 80 integrated circuit, 90 voltage control circuit, 100 image processing device.

Claims (8)

An image processing unit that executes image processing using one or more of the multiple modules used in each operation mode of image processing, and an image processing unit.
A storage unit that stores power consumption information indicating the power consumption of the plurality of modules for each module, and
A derivation unit that derives the total power consumption of one or more modules used in each operation mode of image processing by the image processing unit from the power consumption of each module shown in the power consumption information.
The operation of the module used in each operation mode of image processing according to the control conditions of the module determined for each operation mode so that the total power consumption derived by the derivation unit does not exceed a predetermined allowable amount. And the control unit that controls
Have,
An image processing device characterized by this. In the image processing apparatus according to claim 1,
The control unit is at least one used in the operation mode according to the control conditions corresponding to the operation mode when the total power consumption of each operation mode derived by the derivation unit exceeds the allowable amount. Stop the operation of the module,
An image processing device characterized by this. In the image processing apparatus according to claim 1 or 2.
The control unit is at least one used in the operation mode according to the control conditions corresponding to the operation mode when the total power consumption of each operation mode derived by the derivation unit exceeds the allowable amount. Change the module to a low power module that consumes less power than the module.
An image processing device characterized by this. In the image processing apparatus according to any one of claims 1 to 3,
When the total power consumption of each operation mode derived by the derivation unit exceeds the permissible amount, the control unit is executed in parallel in the operation mode according to the control conditions corresponding to the operation mode. Change at least some of the parallel modules to time division execution,
An image processing device characterized by this. In the image processing apparatus according to any one of claims 1 to 4.
The power consumption of each module shown in the power consumption information is corrected according to the manufacturing variation of the integrated circuit having the image processing function.
The derivation unit derives the total power consumption based on the corrected power consumption information.
An image processing device characterized by this. In the image processing apparatus according to any one of claims 1 to 5,
An integrated circuit having the image processing function and
A voltage control circuit that controls the voltage applied to the integrated circuit, and
Have more
The integrated circuit outputs internal voltage information indicating the voltage in the integrated circuit.
The voltage control circuit controls the magnitude of the voltage applied to the integrated circuit based on the internal voltage information output from the integrated circuit.
An image processing device characterized by this. In the image processing apparatus according to claim 6,
The internal voltage information includes information indicating a voltage corresponding to the current time in the integrated circuit and information indicating that the voltage in the integrated circuit changes from the voltage corresponding to the current time.
An image processing device characterized by this. Computer,
A storage means for storing power consumption information indicating the power consumption of a plurality of modules used in each operation mode of image processing for each module.
A derivation means for deriving the total power consumption of one or more modules used in each operation mode of image processing from the power consumption of each module shown in the power consumption information.
The operation of the module used in each operation mode of image processing according to the control conditions of the module determined for each operation mode so that the total power consumption derived by the derivation means does not exceed a predetermined allowable amount. Control means to control
A program that functions as.