JP2018055615A - Information processing device, information processing system, and information processing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To distribute loads of a device to another device in view of remaining battery capacity of the another device.SOLUTION: There is provided an information processing device including a control part which acquires information of a required CPU processing amount and a required memory region in processing to be executed, acquires, from two or more other information processing devices having a battery, a CPU, and a memory, information of a residual battery amount, a free CPU processing amount, and a free memory region of the other information processing devices, and based on the required CPU processing amount, the required memory region, the residual battery amount, the free CPU processing amount, and the free memory region, determines the CPU and the memory of one of the other information processing device for executing the processing.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an information processing apparatus, an information processing system, and an information processing method.

A vehicle or the like is equipped with a multimedia device (Multi Media device, MM device) having a car navigation function or the like. In an MM device mounted on a vehicle or the like, in addition to a car navigation function, for example, a function of displaying a vehicle state, a function of adjusting an air conditioner of a vehicle, an audio function, a function of performing a voice call, and the like are realized.

JP 2004-246692 A JP 2006-65725 A Japanese Patent Laid-Open No. 07-175768 JP 2010-86145 A

  Due to the evolution of graphics, applications, networks, etc., the performance required for MM devices is increasing year by year. In particular, demands for CPUs and memories are increasing, but due to cost constraints, devices are designed with limited resources. Depending on the use case, the resource may be used up, resulting in performance degradation such as deterioration in the response of the MM device. In addition, since the MM device is fixed and mounted on the vehicle, it is difficult to update the hardware of the MM device, but it is easy to update the software of the MM device. If the software of the MM device is updated without updating the hardware of the MM device, a resource shortage of the MM device may occur. On the other hand, an external device such as a mobile terminal may be communicably connected to the MM device. In an external device, there may be room for resources depending on the situation. However, external devices such as portable terminals are often driven by a battery, and attention to the remaining battery level of the external device is required during use. Therefore, it is required to reduce the load of the MM device by distributing the load of the MM device to the external device connected to the MM device in consideration of the remaining battery level of the external device.

  It is an object of the present invention to distribute the load of a device to other devices while considering the remaining battery level of the other devices.

In order to solve the above problems, the present invention employs the following means.
That is, the first aspect is
In the process to be executed, the CPU processing amount required and information on the memory area required are acquired,
Obtain information on the remaining battery capacity of the other information processing apparatus, the CPU free processing amount, and the memory free area from two or more other information processing apparatuses having a battery, a CPU, and a memory,
The other information for executing the processing based on the required CPU processing amount, the required memory area, the remaining battery level, the CPU free processing amount, and the memory free space A controller for determining the CPU and the memory of the processing device;
An information processing apparatus is assumed.
An aspect of the disclosure may be realized by executing a program by an information processing device. That is, the disclosed configuration can be specified as a program for causing the information processing apparatus to execute the processing executed by each unit in the above-described aspect, or a computer-readable recording medium on which the program is recorded. Further, the disclosed configuration may be specified by a method in which the information processing apparatus executes the process executed by each of the above-described units. The configuration of the disclosure may be specified as a system including an information processing apparatus that performs the processing executed by each of the above-described units.

  According to the present invention, the load of a device can be distributed to other devices while considering the remaining battery level of the other devices.

FIG. 1 is a diagram illustrating a configuration example of a system according to the embodiment. FIG. 2 is a diagram illustrating an example of functional blocks of the MM device in the embodiment. FIG. 3 is a diagram illustrating an example of functional blocks of the external device according to the embodiment. FIG. 4 is a diagram illustrating a hardware configuration example of a computer. FIG. 5 is a diagram illustrating an example (1/3) of an operation sequence of the system according to the embodiment. FIG. 6 is a diagram illustrating an example (2/3) of the operation sequence of the system according to the embodiment. FIG. 7 is a diagram illustrating an example (3/3) of the operation sequence of the system according to the embodiment. FIG. 8 is a diagram illustrating an example of specifications of an external device stored in the storage unit of the MM device.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The configuration of the following embodiment is an exemplification, and the present invention is not limited to the configuration of the embodiment.

<Embodiment>
(Configuration example)
FIG. 1 is a diagram illustrating a configuration example of a system according to the present embodiment. The system 10 in FIG. 1 includes an MM device 100, an external device 200A, and an external device 200B. The MM device 100 is communicably connected to the external device 200A and the external device 200B. The MM device 100 is, for example, an in-vehicle device mounted on a vehicle. The external device 200A and the external device 200B are, for example, a mobile terminal, a PC, a server, and the like. When the external device 200A and the external device 200B are not distinguished, they are collectively referred to as the external device 200. In the example of FIG. 1, the number of external devices 200 is two. However, in the system 10, the number of external devices 200 may be one or three or more. The MM device 100 and the external device 200 are examples of information processing apparatuses.

  The MM device 100 includes, for example, a car navigation function, a function for displaying a vehicle state, a function for adjusting a vehicle air conditioner, an audio function, a function for performing a voice call, and the like. The MM device 100 is communicably connected to the external device 200 via Bluetooth (registered trademark), a wireless LAN, or the like. The MM device 100 may realize a function such as a voice call by using a mobile phone or the like as the external device 200 as a relay device. When the resources (CPU and memory) of the MM device 100 are insufficient, the MM device 100 temporarily rents the resource of the external device 200 (the external device 200 receives the resource of the external device 200 with the MM device 100). By causing the processing to be executed), the load on the MM device 100 side is reduced.

  The external device 200 is a device such as a mobile terminal. The external device 200 is connected to the MM device 100 so that communication is possible. Each external device 200 may be communicably connected to another external device 200. The external device 200 includes a battery as a power source for driving the external device 200. The external device 200 may be temporarily connected to an external power source such as an AC power source and receive power supply for driving.

  FIG. 2 is a diagram illustrating an example of functional blocks of the MM device in the present embodiment. The MM device 100 in FIG. 2 includes a control unit 102, a communication unit 104, a measurement unit 106, and a storage unit 108.

  The control unit 102 performs control of the MM device 100, a resource confirmation request for the MM device 100 and the external device 200, selection of the CPU and memory of the external device 200 to be used, and the like.

  The communication unit 104 transmits and receives information to and from the external device 200 and the like in both directions.

  The measurement unit 106 measures the usage status of resources (CPU, memory, etc.) of the MM device 100.

  The storage unit 108 stores data used by the MM device 100, data received from the external device 200, and the like.

  FIG. 3 is a diagram illustrating an example of functional blocks of the external device according to the present embodiment. The external device 200 of FIG. 3 includes a control unit 202, a communication unit 204, a measurement unit 206, and a storage unit 208.

  The control unit 202 performs control of the external device 200, a resource measurement instruction of the external device 200, and the like.

  The communication unit 204 transmits and receives data (information) bidirectionally between the MM device 100 and another external device 200.

  The measurement unit 206 measures the usage status of the resources (CPU, memory, battery, etc.) of the external device 200.

  The storage unit 208 stores data used by the external device 200, data received from the MM device 100 and other external devices 200, and the like. The storage unit 208 stores identification information for identifying the own device (external device 200).

The MM device 100 can be realized using a dedicated or general-purpose computer such as a smartphone, a mobile phone, a tablet terminal, or a car navigation device, or an electronic device equipped with a computer. The external device 200 includes a PC (Personal Computer), a workstation (WS: Work Station), a smartphone, a mobile phone,
This can be realized by using a dedicated or general-purpose computer such as a tablet terminal, a car navigation device, a PDA (Personal Digital Assistant), or an electronic device equipped with a computer.

FIG. 4 is a diagram illustrating a hardware configuration example of a computer. A computer 90 shown in FIG. 4 has a general computer configuration. The MM device 100 and the external device 200 are realized by using a computer 90 as shown in FIG. 4 includes a processor 91, a memory 92, a storage unit 93, an input unit 94, an output unit 95, and a communication control unit 96. These are connected to each other by a bus. The memory 92 and the storage unit 93 are computer-readable recording media. The hardware configuration of the computer is not limited to the example shown in FIG. 4, and omissions, replacements, and additions of components may be performed as appropriate.

  In the computer 90, the processor 91 loads a program stored in the recording medium into the work area of the memory 92 and executes it, and each component is controlled through the execution of the program, so that a function that matches a predetermined purpose is obtained. Can be realized.

  The processor 91 is, for example, a CPU (Central Processing Unit) or a DSP (Digital Signal Processor).

  The memory 92 includes, for example, a RAM (Random Access Memory) and a ROM (Read Only Memory). The memory 92 is also called a main storage device.

The storage unit 93 is, for example, an EPROM (Erasable Programmable ROM) or a hard disk drive (HDD, Hard Disk Drive). The storage unit 93 can include a removable medium, that is, a portable recording medium. The removable media is, for example, a USB (Universal Serial Bus) memory or a disc recording medium such as a CD (Compact Disc) or a DVD (Digital Versatile Disc). The storage unit 93 is also called a secondary storage device.

  The storage unit 93 stores various programs, various data, and various tables in a recording medium in a readable and writable manner. The storage unit 93 stores an operating system (OS), various programs, various tables, and the like. Information stored in the storage unit 93 may be stored in the memory 92. In addition, information stored in the memory 92 may be stored in the storage unit 93.

  The operating system is software that mediates software and hardware, manages memory space, manages files, manages processes and tasks, and the like. The operating system includes a communication interface. The communication interface is a program for exchanging data with other external devices connected via the communication control unit 96. Examples of the external device include another computer and an external storage device.

  The input unit 94 includes a keyboard, a pointing device, a wireless remote controller, a touch panel, and the like. The input unit 94 may include a video / image input device such as a camera, and an audio input device such as a microphone.

The output unit 95 includes an LCD (Liquid Crystal Display), an EL (Electroluminescence) panel, a CRT (Cathode Ray Tube) display, a display device such as a PDP (Plasma Display Panel), and an output device such as a printer. The output unit 95 can include an audio output device such as a speaker.

  The communication control unit 96 is connected to another device and controls communication between the computer 90 and the other device. The communication control unit 96 is, for example, a LAN (Local Area Network) interface board, a wireless communication circuit for wireless communication, or a communication circuit for wired communication. The LAN interface board and the wireless communication circuit are connected to a network such as the Internet.

  The computer that realizes the MM device 100, the external device 200A, and the external device 200B loads the control unit 102, the communication unit 104, and the measurement by the processor loading and executing the program stored in the auxiliary storage device. Functions of the unit 106, the control unit 202, the communication unit 204, and the measurement unit 206 are realized. On the other hand, the storage unit 108 and the storage unit 208 are provided in a storage area of the main storage device or the auxiliary storage device.

(Operation example)
5, 6, and 7 are diagrams illustrating an example of an operation sequence of the system according to the present embodiment. “A”, “B”, and “C” in FIG. 5 are connected to “A”, “B”, and “C” in FIG. 6, respectively. “D”, “E”, and “F” in FIG. 6 are connected to “D”, “E”, and “F” in FIG. 7, respectively.

  The operation sequence of FIG. 5 and the like is started when, for example, the MM device 100 tries to execute some processing (for example, tries to start some application). The operation sequence of FIG. 5 or the like may be started by an input operation from the user of the MM device 100. It is assumed that a program for executing this operation sequence is installed in the MM device 100 and each external device 200 in advance.

In SQ101, the control unit 102 of the MM device 100 acquires information on resources (necessary resources) required for the process to be executed by the MM device 100. The required resource information includes the processing amount (MIPS (Million Instructions Per Second) unit) in the CPU for executing the processing, the memory area used for executing the processing (Byte unit), and the processing is executed. Communication speed (bus width) (bps unit) necessary for the transmission is included. The required communication speed is the minimum communication speed required when the required resource is obtained from the external device 200. In the case of a process with many data exchanges, if the communication speed is low, the process to be executed may not be performed even if the CPU and memory conditions are satisfied. For example, the necessary resource information is stored in the storage unit 108 in advance for each process to be executed. The storage unit 108 stores specifications of the MM device 100 in advance. The specifications include the maximum performance of the CPU of the MM device 100 (MIPS unit), the memory area of the MM device 100 (Byte unit), and the like. The control unit 102 acquires resource information necessary for the process to be executed from the storage unit 108. In this sequence, an external device 200 (CPU, memory) that provides a resource for executing a process to be executed is determined.

  In SQ102, the control part 102 makes the measurement part 106 measure the utilization condition of the resource of an own apparatus (MM apparatus 100). The measuring unit 106 measures the usage status (load) of the CPU of its own device and the memory usage area. The measurement unit 106 stores the measurement result in the storage unit 108.

  In SQ 103, the control unit 102 acquires the specifications of the MM device 100 and the measurement result in SQ 102 from the storage unit 108. The control unit 102 calculates a free CPU processing amount and a free memory area from the specifications of the MM device 100, the CPU usage status, and the memory use area. The control unit 102 compares the necessary resources, the CPU free processing amount, and the memory free area, and determines whether or not the processing to be executed by the MM device 100 can be executed by the MM device 100. The control unit 102 determines that the process to be executed by the MM device 100 can be executed by the MM device 100 when the CPU free processing amount and the memory free space satisfy the necessary resources. If it can be executed, the control unit 102 uses the CPU and memory of the MM device 100 to execute the process to be executed. In this case, the subsequent processing is not performed. When at least one of the free processing amount of the CPU and the free area of the memory does not satisfy the necessary resource, the process proceeds to the next process.

  In SQ 104, the control unit 102 of the MM device 100 transmits a specification confirmation request to each external device 200 via the communication unit 104. The specifications are the maximum performance of the CPU of each external device 200 and the memory area (in bytes). The specifications of the own device are stored in advance in the storage unit 208 of each external device 200. The control unit 202 of each external device 200 receives a specification confirmation request via the communication unit 204. The control unit 202 of each external device 200 acquires the specifications of the own device stored in the storage unit 208.

  In SQ 105, the control unit 202 of each external device 200 transmits the specification acquired from the storage unit 208 to the MM device 100 through the communication unit 204 together with identification information for identifying each external device 200. When receiving the specification from the external device 200 via the communication unit 104, the control unit 102 of the MM device 100 stores the specification along with the identification information of the external device 200 in the storage unit 108.

  FIG. 8 is a diagram illustrating an example of specifications of an external device stored in the storage unit of the MM device. In the example of FIG. 8, the maximum performance of the CPU of the external device 200A (external device A) is 10,000 MIPS, the memory area is 2 GB, the maximum performance of the CPU of the external device 200B (external device B) is 2500 MIPS, and the memory area is 512 MB. Is shown.

  The control unit 102 does not need to transmit subsequent requests to the external device 200 whose specifications received in SQ 105 do not satisfy the required specifications. This is because the external device 200 that does not satisfy the necessary specifications cannot execute the process to be executed. As a result, the amount of communication between the MM device 100 and the external device 200 can be reduced.

  In SQ 106, the control unit 102 of the MM device 100 transmits a battery remaining amount confirmation request to each external device 200 via the communication unit 104. The battery remaining capacity is a remaining capacity of a battery as a power source for driving each external device 200. A low battery level indicates that it is difficult to provide resources. If the external device 200 uses an AC power source or the like instead of a battery, the remaining battery capacity may be 100%.

  The control unit 202 of each external device 200 receives a battery remaining amount confirmation request via the communication unit 204. The control unit 202 of each external device 200 causes the measurement unit 206 to measure the remaining battery level of its own device. The remaining battery capacity may be a ratio of the remaining capacity to the full charge or may be an absolute amount (Ah unit) of the remaining capacity. The measuring unit 206 measures the remaining battery level of the own device. The measurement unit 206 stores the measured remaining battery level in the storage unit 208.

  In SQ 107, the control unit 202 of each external device 200 transmits the remaining battery level measured by the measurement unit 206 to the MM device 100 via the communication unit 204 together with identification information for identifying each external device 200. When the control unit 102 of the MM device 100 receives the remaining battery level from the external device 200 via the communication unit 104, the control unit 102 stores it in the storage unit 108 together with the identification information of the external device 200.

  The control unit 102 does not need to transmit subsequent requests to the external device 200 whose remaining battery level received in SQ 107 is less than a predetermined value. This is because, in the external device 200 whose battery remaining amount is less than the predetermined value, the process may stop due to insufficient power during the execution of the process to be executed. The predetermined value here may be set in advance by a user of the external device 200 or the like, and may be notified from the external device 200 to the MM device 100 when the operation sequence is executed. When the external device 200 does not want to provide resources, the predetermined value here may be set to the maximum value of the remaining battery level.

  Moving to FIG. 6, in SQ 108, the control unit 102 of the MM device 100 transmits a resource availability confirmation request to each external device 200 via the communication unit 104. The resource availability status includes the CPU free processing amount and the memory free space of each external device 200. The CPU idle processing amount is obtained by subtracting the CPU use processing amount (CPU load) from the CPU maximum performance. The free memory area is obtained by subtracting the memory use area from the memory area.

  The control unit 202 of each external device 200 receives a resource availability confirmation request via the communication unit 204. The control unit 202 of each external device 200 causes the measurement unit 206 to measure the resource availability check of its own device. The measuring unit 206 measures the resource availability status of the own device (a CPU free processing amount and a memory free area). The measurement unit 206 stores the measured resource availability in the storage unit 208.

  In SQ 109, the control unit 202 of each external device 200 transmits the resource availability measured by the measurement unit 206 to the MM device 100 via the communication unit 204 together with identification information for identifying each external device 200. When receiving the resource availability from the external device 200 via the communication unit 104, the control unit 102 of the MM device 100 stores the resource availability together with the identification information of the external device 200 in the storage unit 108.

  The control unit 102 does not need to transmit subsequent requests to the external device 200 whose resource availability (both CPU and memory) received in SQ 109 does not satisfy the required specifications. This is because the external device 200 whose resource availability does not satisfy the required specifications cannot execute the process to be executed.

  In SQ 110, the control unit 102 of the MM device 100 transmits a request for maximum load factor confirmation to each external device 200 via the communication unit 104. The maximum load factor is a load factor when resources are most frequently used in the latest predetermined period (for example, the latest one minute). For example, in a CPU having a maximum performance of 10,000 MIPS, when a maximum of 4000 MIPS is used in the most recent predetermined period, the maximum load factor in the most recent predetermined period is 40%. Further, in a memory having a capacity of 2 GB, when 1.2 GB at maximum is used in the most recent predetermined period, the maximum load factor in the most recent predetermined period is 60%.

  The control unit 202 of each external device 200 receives a request for maximum load factor confirmation via the communication unit 204. The control unit 202 of each external device 200 causes the measurement unit 206 to obtain the maximum load factor of the own device. The measuring unit 206 obtains the maximum load factor (CPU and memory) of the device itself for the most recent predetermined period. The measuring unit 206 stores the obtained maximum load factor in the storage unit 208. The measuring unit 206 of each external device 200 may always measure the resource availability from the time when the operation sequence is started, and may be used as the storage unit 208. At this time, the measurement unit 206 extracts the resource vacancy status for the most recent predetermined period from the storage unit 208, and determines the own device for the most recent predetermined period from the minimum CPU free processing amount and the minimum memory free area. The maximum load factor may be obtained.

  In SQ 111, the control unit 202 of each external device 200 transmits the maximum load factor measured by the measurement unit 206 to the MM device 100 via the communication unit 204 together with identification information for identifying each external device 200. When receiving the maximum load factor from the external device 200 via the communication unit 104, the control unit 102 of the MM device 100 stores the maximum load factor in the storage unit 108 together with the identification information of the external device 200.

  The control unit 102 does not transmit a subsequent request to the external device 200 in which the minimum available resource in the most recent predetermined period obtained from the maximum load factor in the most recent predetermined period received in SQ 111 does not satisfy the required specifications. May be. This is because the external device 200 whose minimum free resource does not satisfy the required specifications may not be able to execute the process to be executed due to insufficient resources. In the resource vacancy situation of S109, even if the required specifications are satisfied, if the required specifications are not satisfied in the most recent predetermined period, it is expected that the load fluctuation in the external device 200 will be large, which is not suitable for providing resources. it is conceivable that. Here, the external device 200 that is not suitable for providing a resource is excluded from the candidates for the external device 200 that provides the resource.

  In SQ 112, the control unit 102 of the MM device 100 transmits a communication speed confirmation request to each external device 200 via the communication unit 104. The communication speed is a communication speed (bus width) between the external device 200 and the MM device 100. The control unit 202 of each external device 200 receives a communication speed confirmation request via the communication unit 204. The control unit 202 of each external device 200 investigates the communication speed with the MM device 100.

  In SQ 113, the control unit 202 of each external device 200 transmits the investigated communication speed to the MM device 100 together with identification information for identifying each external device 200 via the communication unit 204. When receiving the communication speed from the external device 200 via the communication unit 104, the control unit 102 of the MM device 100 stores it in the storage unit 108 together with the identification information of the external device 200.

  Moving to FIG. 7, in SQ 114, the control unit 102 of the MM device 100 selects the CPU and memory of the external device 200 that requests resource provision. The control unit 102 selects the CPU and memory of the external device 200 that requests resource provision based on the specifications, battery remaining capacity, resource availability, maximum load factor, communication speed, and required specifications of each external device 200. The CPU and the memory may be selected from separate external devices 200. The control unit 102 satisfies the required specification, the remaining battery level is equal to or greater than a predetermined value, the resource availability satisfies the required specification, the resource availability in the latest predetermined period satisfies the required specification, and the communication speed is A CPU and memory requesting resource provision are selected from CPU and memory candidates that satisfy the required specifications. When there are a plurality of candidates, a CPU and memory with higher specifications are selected. By selecting a higher-spec CPU and memory, it becomes difficult to affect the processing in the selected external device 200 by providing resources. In addition, when there is no candidate, the process to be executed cannot be executed.

  In SQ115, the control unit 102 of the MM device 100 communicates data and the like necessary for executing the processing to be executed to the external device 200 having the CPU selected in SQ114 and the external device 200 having a memory. The data is transmitted via the unit 104. When the control unit 202 of the selected external device 200 receives the necessary data via the communication unit 204, the control unit 202 executes a process to be executed using the selected CPU and memory, and if necessary, The data is transmitted to the MM device 100. Thereby, the MM device 100 provides resources (necessary resources) for executing the processing to be executed by the CPU and the memory of the external device 200.

  Further, after a predetermined time has elapsed, the control unit 102 of the MM device 100 repeats the operation sequence after SQ106. Thereby, the external device 200 whose remaining battery level is less than the predetermined value can be excluded from candidates for providing resources. Furthermore, it is possible to cope with the time change of the resource availability of the external device 200. At this time, the measurement unit 206 of the external device 200 may measure the resource provided to the MM device 100 as a free resource. Moreover, the control part 102 may repeat the operation | movement sequence of SQ106, SQ107, SQ114, and SQ115 for every predetermined time. Thereby, paying attention only to the remaining battery level, the external device 200 whose remaining battery level is less than the predetermined value can be excluded from the candidates for providing the resource, and the resource can be provided from another external device 200. it can.

  In the above operation sequence, the order can be changed as appropriate.

A program for executing the above operation sequence is installed in each of the MM device 100 and each external device 200. A program installed in the MM device 100 may be installed in the external device 200A, and a program installed in the external device 200 may be installed in the MM device 100 and the external device 200B. At this time, the external device 200A can borrow resources of the MM device 100 and the external device 200B. Further, a single program in which a program installed in the MM device 100 and a program installed in the external device 200 are integrated may be installed in the MM device 100 and each external device 200. At this time, each device can borrow resources from other devices or lend resources to other devices depending on the situation.

(Operation and effect of the embodiment)
According to the system 10 of the present embodiment, the MM device 100 can receive as many resources as necessary from the external device 200 that can be provided in accordance with the CPU and memory status of the changing external device 200.

  The MM device 100 checks the availability of the CPU and memory, which are resources of the connected external device 200, and determines the CPU and memory that are provided with resources for the processing to be executed.

  Due to the evolution of graphics, applications, networks, etc., the performance required for MM devices is increasing year by year. In particular, demands for CPUs and memories are increasing, but due to cost constraints, devices are designed with limited resources. Depending on the use case, the resource may be used up, resulting in performance degradation such as deterioration in the response of the MM device. In addition, since the MM device is fixed and mounted on the vehicle, it is difficult to update the hardware of the MM device, but it is easy to update the software of the MM device.

  According to the system 10, when the software of the MM device 100 is updated without updating the hardware of the MM device 100, the resource is provided from the external device 200 even if the resource of the MM device 100 is insufficient. Thus, the resource shortage of the MM device 100 can be compensated (the load on the MM device 100 is reduced). Further, the MM device 100 can receive a resource while considering the remaining battery level of the external device 200 by examining the remaining battery level of the external device 200.

  The embodiments of the present invention have been described above. However, these are merely examples, and the present invention is not limited to these embodiments. Various modifications based on the knowledge of those skilled in the art can be made without departing from the spirit of the claims. Can be changed. Moreover, each structural example etc. may be combined and implemented as much as possible.

<Computer-readable recording medium>
A program for causing a computer or other machine or device (hereinafter, a computer or the like) to realize any of the above functions can be recorded on a recording medium that can be read by the computer or the like. The function can be provided by causing a computer or the like to read and execute the program of the recording medium.

  Here, a computer-readable recording medium is a recording medium that stores information such as data and programs by electrical, magnetic, optical, mechanical, or chemical action and can be read from a computer or the like. Say. In such a recording medium, elements constituting a computer such as a CPU and a memory may be provided to cause the CPU to execute a program.

  Examples of such a recording medium that can be removed from a computer or the like include a flexible disk, a magneto-optical disk, a CD-ROM, a CD-R / W, a DVD, a DAT, an 8 mm tape, and a memory card.

  Moreover, there are a hard disk, a ROM, and the like as a recording medium fixed to a computer or the like.

10 system
100 MM equipment
101 Control unit
102 Communication Department
103 Measuring unit
104 Storage unit
200 External equipment
201 Control unit
202 Communication unit
203 Measuring unit
204 Storage unit
90 computers
91 processor
92 memory
93 Memory
94 Input section
95 Output section
96 Communication control unit

Claims (6)

In the process to be executed, the CPU processing amount required and information on the memory area required are acquired,
Obtain information on the remaining battery capacity of the other information processing apparatus, the CPU free processing amount, and the memory free area from two or more other information processing apparatuses having a battery, a CPU, and a memory,
The other information for executing the processing based on the required CPU processing amount, the required memory area, the remaining battery level, the CPU free processing amount, and the memory free space A controller for determining the CPU and the memory of the processing device;
Information processing device. The control unit acquires the maximum performance of the CPU and the memory area of the other information processing apparatus, and executes the processing based on the maximum performance of the CPU and the memory area. Determining the CPU and the memory of the information processing apparatus;
The information processing apparatus according to claim 1. The said control part acquires the communication speed required by the said process, and the said CPU of the said other information processing apparatus for performing the said process based on the communication speed between the said other information processing apparatuses And determining the memory,
The information processing apparatus according to claim 1 or 2. The control unit is configured to execute the processing on a CPU in which the remaining amount of the battery is equal to or greater than a predetermined value and a free processing amount of the CPU is equal to or greater than the required processing amount of the CPU. And determining the memory whose remaining amount is equal to or greater than a predetermined value and the free area of the memory is equal to or greater than the required memory area as the memory for executing the processing,
The information processing apparatus according to any one of claims 1 to 3. An information processing system including a first information processing device and two or more second information processing devices having a battery, a CPU, and a memory,
The first information processing apparatus is
In the process to be executed, the CPU processing amount required and information on the memory area required are acquired,
From the second information processing device, obtain information on the remaining battery capacity of the second information processing device, the CPU free processing amount, and the memory free space,
The other information for executing the processing based on the required CPU processing amount, the required memory area, the remaining battery level, the CPU free processing amount, and the memory free space A control unit for determining the CPU and the memory of the processing device;
The second information processing apparatus is
The first information processing apparatus includes a control unit that provides information on a remaining battery level of the own apparatus, an empty processing amount of the CPU, and an empty area of the memory.
Information processing system. Computer
In the process to be executed, the CPU processing amount required and information on the memory area required are acquired,
Obtaining information on the remaining battery capacity of the information processing apparatus, the CPU free processing amount, and the memory free area from two or more information processing apparatuses having a battery, a CPU, and a memory;
The information processing apparatus for executing the processing based on the required CPU processing amount, the required memory area, the remaining battery capacity, the free CPU processing amount, and the free memory area. Determining the CPU and the memory of
An information processing method that executes things.

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