JP5685366B2 - Information processing apparatus, power saving program, and power saving method - Google Patents

Description

  The present invention relates to an information processing apparatus that can save power by detecting a user's absence state.

  Conventionally, a technique for detecting the absence state of a user of an information processing apparatus has been realized. Applying technology to detect presence / absence status, for example, when a user is away from the seat, for example, a power supply to a monitor (display unit) connected to or built in the information processing device used by the user Some devices achieve power saving by shifting to a power saving mode such as cutting the supply.

  By the way, in the information processing apparatus that detects the user's away state using the distance measuring sensor, the sensor measures the distance between the sensor and the object and detects that the object exists at a predetermined distance. Even when the sensor detects an object other than the human body in order to determine that the user is present, the user may be determined to be present.

  Therefore, a human body can be detected by providing both a sensor (hereinafter referred to as a “pyroelectric sensor”) that can detect the presence of a human body using radiant heat from the human body and a ranging sensor. There is.

  Patent Document 1 discloses a human body detection device that detects a human body by combining an immediate distance sensor and a pyroelectric sensor.

JP-A-6-242258

  By the way, since the pyroelectric sensor determines that a human body has been detected if there is a heat source around it, a malfunction may occur. For this reason, conventionally, as described above, the probability of detecting a human body is increased by combining with a distance measuring sensor.

  However, since the human body detection apparatus as described above needs to include both the distance measuring sensor and the pyroelectric sensor, there is a problem that it is expensive.

  In addition, when the human body detection device as described above is applied to an information processing device, there is a problem that the housing of the information processing device becomes large by mounting a plurality of sensors.

  Therefore, an object of the present invention is to provide an information processing apparatus that can detect the state of a user's absence by using only a pyroelectric sensor to save power.

  The first information processing apparatus according to the present invention includes a control unit that shifts to a power saving mode when the heat detection unit that detects radiant heat from a human body detects radiant heat that moves upward. And

  The second information processing apparatus of the present invention further cancels the power saving mode when the second heat detection means for detecting radiant heat from a human body from a wider range than the heat detection means detects the radiant heat. A second control means is provided.

Third information processing apparatus of the present invention is an information processing apparatus including a heat detector for detecting the radiant heat from the human body, the thermal detection means, heat transfer detection for detecting the radiant heat moves upward And the absence determination means for determining that the user has left when the heat movement detection means detects the radiant heat moving upward, and the absence determination means that the user has left the seat. And a control means for shifting to the power saving mode.

The fifth information processing apparatus of the present invention includes storage means for storing at least pattern information indicating the absence state and pattern information indicating the presence state, and the absence determination means is detected by the thermal movement detection means. When the pattern information indicating the state of the radiant heat moving in the direction matches the stored pattern information indicating the away state, it is determined that the user has left the seat .

  The power saving program of the present invention is a power saving program of an information processing apparatus including a heat detecting means for detecting radiant heat from a human body, and a heat transfer detecting step for detecting radiant heat moving in an upward direction, And a control step of shifting to a power saving mode when radiant heat moving in the upward direction is detected in the heat transfer detecting step.

  The power saving method of the present invention is a power saving program for an information processing apparatus including a heat detecting means for detecting radiant heat from a human body, and a heat transfer detecting step for detecting radiant heat moving in an upward direction, And a control step of shifting to a power saving mode when radiant heat moving in the upward direction is detected in the heat transfer detecting step.

  According to the present invention, it is possible to provide an information processing apparatus that can detect the state of a user's absence using only a pyroelectric sensor and can save power.

It is a block diagram for demonstrating the information processing apparatus of embodiment of this invention. It is a flowchart for demonstrating operation | movement of the information processing apparatus of embodiment of this invention. It is an example of the away pattern of embodiment of this invention. It is an example of the presence pattern of embodiment of this invention. It is a block diagram for demonstrating the information processing apparatus of embodiment of this invention. It is a flowchart for demonstrating operation | movement of the information processing apparatus of embodiment of this invention. It is a figure for demonstrating the difference in the width of the detection range of the monocular lens of the information processing apparatus of embodiment of this invention, and a multi-lens lens.

  The best mode for carrying out the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram for explaining the information processing apparatus according to the present embodiment.

  Referring to FIG. 1, the information processing apparatus 10 includes a control unit 20, a detection unit 30, a display unit 40, and a storage unit 50.

  First, the outline of the information processing apparatus 10 according to the present embodiment will be described. When the information processing apparatus 10 is activated, the detection unit 30 detects the radiant heat around the information processing apparatus 10 and detects the detected radiant heat. When a predetermined pattern is detected from the pattern information indicating this state, it is determined that the user has left the seat and the power of the display unit 40 is turned off. Details will be described below.

  The control unit 20 logically includes a determination unit 21 and a display control unit 22 by reading and executing a program stored in the recording medium. Note that the determination unit 21 and the display control unit 22 may each be configured by dedicated hardware.

  The detection unit 30 is a pyroelectric sensor, and is mounted on the information processing apparatus 10 so as to face the user. The detection unit 30 detects ambient radiant heat via a sensor.

  The display unit 40 is a display display device. Specifically, when the information processing apparatus 10 is a notebook personal computer, the display display screen is integrated with the information processing apparatus 10. When the information processing apparatus 10 is a desktop personal computer, the display unit 40 may be configured not to be built in the information processing apparatus 10 but connected.

  The storage unit 50 is a storage device such as a hard disk device built in the information processing apparatus 10, for example.

  Next, the operation of this embodiment will be described with reference to FIG. FIG. 2 is a flowchart for explaining the operation of the present embodiment.

  Referring to FIG. 2, when the information processing apparatus 10 is activated, the detection unit 30 starts detecting the state of radiant heat (step S1).

  When the state of the radiant heat is detected in step S1, the determination means 21 has a pattern indicating that the state of the radiant heat detected in step S1 indicates a away state or is stored in the storage unit 50. Judgment is made based on whether or not the pattern matches the state pattern indicating the state (step S2).

  Specifically, the pattern indicating the away state refers to a pattern indicating a state in which radiant heat moves upward. When the user leaves the seat, the user takes the action of standing up, so that the user's body moves upward. If the user's body moves upward, a pattern in which radiant heat moves upward is detected. Accordingly, when a pattern indicating a state in which the radiant heat moves upward is detected, it is determined that the user has left his / her seat.

  FIG. 3 is an example of a pattern showing a state in which radiant heat moves upward. As shown in FIG. 3, in a state where the radiant heat moves upward (that is, when the user leaves the seat), there is an extreme change in numerical value.

  When a pattern that matches the pattern indicating the absence state is detected in step S2, the display control unit 22 shifts the information processing apparatus 10 to the power saving mode (step S3).

  The power saving mode refers to, for example, a state where power supply to the display unit 40 is temporarily stopped and a state where power supply to the storage unit 50 is temporarily stopped. Further, the power saving mode may be a state in which the system of the information processing apparatus 10 is suspended.

  In the present embodiment, when the mode is shifted to the power saving mode, the display control unit 22 stops the power supply to the display unit 40.

  Note that the display control unit 22 may turn off the display unit 40 after waiting for a predetermined time after the pattern indicating the absence state is detected. In this case, a configuration may be adopted in which, when an operation on the information processing apparatus 10 by the user is detected during the standby time, the mode is not shifted to the power saving mode.

  If no pattern indicating the absence state is detected in step S2, the process of proceeding to step S1 is repeated (step S2).

  When the power saving mode is set in step S3, the detection unit 30 starts detecting the radiant heat state again (step S4).

  When the state of radiant heat is detected in step S4, the determination means 21 determines whether or not the detected pattern indicating the state of radiant heat matches the pattern indicating the seated state (step S5).

  FIG. 4 is an example of a pattern showing the state of radiant heat when the user is present. As shown in FIG. 4, when the user is present, there is no extreme change in numerical values.

  When a pattern indicating the presence state is detected in step S5, the display control means 22 shifts from the power saving mode to the normal mode (step S6).

  When shifting from the power saving mode to the normal mode, specifically, the display control unit 22 starts supplying power to the display unit 40. In the power saving mode, when the power supply to the storage unit 50 is stopped, the power supply to the storage unit 50 may be started.

  In step S5, when the detected radiant heat state does not match the pattern indicating the presence state, the process of proceeding to step S4 is repeated (step S5).

  By the way, in the present embodiment, when the pattern indicating the presence state is detected, the display control unit 22 starts to supply power to the display unit 40, but the user is connected to the information processing apparatus 10. The display control unit 22 may start supplying power to the display unit 40 when an input device (not shown) is operated.

  If the normal mode is entered in step S6, the process proceeds to step S2 unless the main body of the information processing apparatus 10 is terminated, and the subsequent processes are repeated (step S7).

  The display control means 22 cuts off the power supply to the display unit 40 when the detection unit 30 detects a pattern in which the user leaves the seat by the processing as described above. As a result, a pattern indicating a state in which the user leaves the seat can be detected only with the pyroelectric sensor, and the power saving effect of the information processing apparatus can be obtained while the user is away from the seat.

  Now, in the above-described processing, when a pattern indicating a state in which the user leaves the seat is detected, the mode can be shifted to the power saving mode. Since there is no transition (return), there is a problem that the transition (return) cannot be performed smoothly.

  Moreover, in a general power saving system, when returning from the power saving mode to the normal mode (transition), the normal mode is restored by detecting that the user performs keyboard input or mouse operation. Most things are not smooth return. There is a demand for the user to detect that he / she returns to his / her seat so that the information processing apparatus can be used immediately.

  Therefore, next, an information processing apparatus that can return to the normal mode from the power saving mode before the user is seated when a movement pattern that returns the user to his / her seat is detected will be described.

  The best mode for carrying out the present invention will be described below with reference to the drawings. FIG. 5 is a block diagram for explaining the information processing apparatus according to the present embodiment.

  Referring to FIG. 5, the information processing apparatus 11 includes a control unit 23, an absence detection unit 31, a return detection unit 32, a display unit 41, and a storage unit 51.

  First, the outline of the information processing apparatus 11 according to the present embodiment will be described. When the information processing apparatus 11 is activated, the absence detection unit 31 detects and detects the radiant heat around the information processing apparatus 11. When a predetermined pattern indicating absence is detected from the pattern information indicating the state of radiant heat, it is determined that the user has left, and power supply to the display unit 41 is interrupted. Further, when the power supply to the display unit 41 is interrupted, the return detection unit 32 detects the surrounding radiant heat, and a predetermined pattern indicating the return is detected from the pattern information indicating the state of the detected radiant heat. In this case, it is determined that the user is seated and the power supply is resumed. Details will be described below.

  The control unit 23 logically includes a determination unit 24, a display control unit 25, and a detection control unit 26 by reading and executing a program stored in the recording medium. The determination unit 24, the display control unit 25, and the detection control unit 26 may each be configured with dedicated hardware.

  The absence detection unit 31 is a pyroelectric sensor and is attached to the information processing apparatus 10 so as to face the user. The absence detection unit 31 detects ambient radiant heat via a sensor.

  The return detection unit 32 is a pyroelectric sensor, and is attached to the information processing apparatus 11 so as to face the user. The return detection unit 32 detects ambient radiant heat via a sensor.

  Here, a difference between the absence detection unit 31 and the return detection unit 32 will be described. The absence detection unit 31 includes, for example, a lens called a Fresnel lens (monocular lens). As a feature of the monocular lens, since the lenses are arranged in a ring shape with the center as a reference, the movement of the heat source of the radiant heat is detected in the central vertical direction as a detection pattern of the radiant heat.

  On the other hand, the return detection unit 32 includes a lens called a Fresnel lens (multi-lens lens). A feature of the multi-lens lens is that a large number of lenses are arranged in a spherical shape and detect heat source movement of a slight radiant heat in a wide range (the direction of detected heat source movement is not limited). In the case of a multi-lens lens, it is possible to detect the movement of a heat source in a relatively wide range, for example, 1 meter.

  FIG. 7 is an image diagram for explaining the difference in detection range between the absence detection unit 31 and the return detection unit 32. As shown in FIG. 7, the detection range between the monocular lens and the multi-lens lens is shown. Have different characteristics.

  The display unit 41 is a display display device. Specifically, when the information processing apparatus 11 is a notebook personal computer, a display display screen integrated with the information processing apparatus 11 is displayed. When the information processing apparatus 11 is a desktop personal computer, the display unit 41 may be configured not to be built in the information processing apparatus 11 but connected.

  The storage unit 51 is a storage device such as a hard disk device built in the information processing apparatus 11, for example.

  Next, the operation of the present embodiment will be described with reference to FIG. FIG. 6 is a flowchart for explaining the operation of the present embodiment.

  Referring to FIG. 6, when the information processing apparatus 10 is activated, the absence detection unit 31 starts detecting the state of radiant heat (step T1).

  When the state of radiant heat is detected in step T1, the determination means 21 has a pattern indicating that the state of radiant heat detected in step T1 indicates a away state, or is stored in the storage unit 51. Judgment is made based on whether or not the pattern matches the state pattern indicating the state (step T2).

  Specifically, the pattern indicating the away state refers to a pattern indicating a state in which radiant heat moves upward. When the user leaves the seat, the user takes the action of standing up, so that the user's body moves upward. If the user's body moves upward, a pattern in which radiant heat moves upward is detected. Accordingly, when a pattern indicating a state in which the radiant heat moves upward is detected, it is determined that the user has left his / her seat.

  In addition, as an example of the pattern which shows the state which radiant heat moves to an upper direction, it becomes a pattern as shown in FIG.

  When a pattern that matches the pattern indicating the absence state is detected in step T2, the display control means 25 shifts the information processing apparatus 11 to the power saving mode (step T3).

  The power saving mode refers to, for example, a state where power supply to the display unit 41 is temporarily stopped or a state where power supply to the storage unit 51 is temporarily stopped. Further, the power saving mode may be a state in which the system of the information processing apparatus 11 is suspended.

  In the present embodiment, when shifting to the power saving mode, the display control means 25 stops the power supply to the display unit 41.

  The display control means 25 may turn off the display unit 41 after waiting for a predetermined time after the pattern indicating the absence state is detected. In this case, a configuration may be adopted in which, when an operation on the information processing apparatus 11 by the user is detected during the standby time, the mode is not shifted to the power saving mode.

  If no pattern indicating the absence state is detected in step T2, the process proceeds to step S1 (step T2).

  Furthermore, if it transfers to a power saving mode by step T3, the detection control means 26 will stop the detection detection part 32 from detecting a heat transfer for a predetermined time (step T4).

  This is because the return detection unit detects heat source movement over a wide range (specifically, about 1 meter range), so the pattern in which the user leaves and moves in either direction is also detected as a return pattern. Because it will end up.

  Here, the predetermined time may be specifically set to 10 seconds, for example, or may be set by the user in advance.

  When a predetermined time elapses after the detection of the return detection unit 32 is stopped in step T4, the detection control unit 26 causes the return detection unit 32 to resume detection of the state of radiant heat (step T5).

  When the state of radiant heat is detected in step T5, the determination means 24 determines whether or not the detected pattern indicating the state of radiant heat matches the pattern indicating the presence state (step T6).

  As described above, since the return detection unit 32 can detect a wide range of heat source movement, it can be detected when the user approaches the vicinity of the seat.

  When a pattern indicating a return state (movement to return to the seat) is detected at step T6 (T6 / YES), the display control means 22 shifts from the power saving mode to the normal mode (step T7).

  When shifting from the power saving mode to the normal mode, specifically, the display control unit 25 starts supplying power to the display unit 41. In the power saving mode, when the power supply to the storage unit 51 is stopped, the power supply to the storage unit 51 may be started.

  In step T7, when the detected radiant heat state does not coincide with the pattern indicating the return state (T6 / NO), the process returns to step T5 and the process is repeated.

  By the way, in this embodiment, when the pattern indicating the return state is detected, the display control means 25 starts to supply power to the display unit 41, but the user is connected to the information processing apparatus 11. The display control means 25 may start supplying power to the display unit 41 when an input device (not shown) is operated.

  In addition, when a pattern indicating the return state is detected, it is preferable that the detection control unit 26 stops the detection of the radiant heat state for a predetermined time. This is because the absence detection unit 31 detects the movement pattern of the heat source in the vertical direction and prevents the user's seating operation from being erroneously detected as the separation pattern.

  If the normal mode is entered in step T8, the process proceeds to step T1 unless the main body of the information processing apparatus 11 is terminated, and the subsequent processes are repeated (step T9).

  Through the processing as described above, the display control unit 25 cuts off the power supply to the display unit 41 when the absence detection unit 31 detects a pattern in which the user leaves the seat. Further, when the return detection unit 32 detects a pattern in which the user approaches the seat, the display control unit 25 resumes power supply to the display unit 41. As a result, a pattern indicating a state in which the user leaves the seat can be detected only with the pyroelectric sensor, and the power saving effect of the information processing apparatus can be obtained while the user is away from the seat. Furthermore, when a pattern indicating a state in which the user returns is detected, the information processing apparatus is returned from the power saving mode to the normal mode, so that the user can work early.

DESCRIPTION OF SYMBOLS 10 Information processing apparatus 20 Control part 21 Determination means 22 Display control means 23 Control part 24 Determination means 25 Display control means 26 Detection control means 30 Detection part 31 Away detection part 32 Return detection part 40 Display part 41 Display part 50 Storage part 51 Memory

Claims (7)

  An information processing apparatus comprising: first control means for shifting to a power saving mode when first heat detection means for detecting radiant heat from a human body detects radiant heat moving upward. .   The second heat detecting means for detecting radiant heat from a human body from a wider range than the first heat detecting means comprises second control means for releasing the power saving mode when radiant heat is detected. The information processing apparatus according to claim 1. An information processing apparatus comprising heat detection means for detecting radiant heat from a human body,
Among the radiant heat detected by the heat detection means, heat transfer detection means for detecting radiant heat moving upward,
When the thermal movement detection means detects radiant heat that moves upward, the absence determination means determines that the user has left, and
An information processing apparatus comprising: a control unit that shifts to a power saving mode when the absence determination unit determines that the user has left. Storage means for storing at least pattern information indicating the absence state and pattern information indicating the presence state;
When the pattern information indicating the state of the radiant heat moving upward detected by the thermal movement detection unit matches the stored pattern information indicating the away state, the absence determination unit determines whether the user has left the seat. The information processing apparatus according to claim 3, wherein the information processing apparatus determines that a seat has been taken. The absence determination unit determines that the user is present when the pattern information indicating the state of radiant heat detected by the thermal movement detection unit matches the stored pattern information indicating the presence state. The information processing apparatus according to claim 4. It is a power saving program for an information processing apparatus including a heat detecting means for detecting radiant heat from a human body, and a heat transfer detecting step for detecting radiant heat moving in an upward direction,
And a control step of shifting to a power saving mode when radiant heat moving in the upward direction is detected in the heat movement detecting step. It is a power saving program for an information processing apparatus including a heat detecting means for detecting radiant heat from a human body, and a heat transfer detecting step for detecting radiant heat moving in an upward direction,
And a control step for shifting to a power saving mode when radiant heat moving in the upward direction is detected in the heat movement detecting step.

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