JP2005006060A - Information processor, information processing method, and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To control the state of a link of communication on the basis of the variation of a radio wave state. <P>SOLUTION: When a link state is judged to be in a sniff mode in a step S1, counting of a timer is started in a step S2. When it is judged in a step S3 that a time Ta has passed, a value RSSI showing the radio wave state is acquired and stored in a step S4, and the variation of the radio wave state is calculated in a step S5. When it is judged in a step S6 that the variation of the radio wave state is equal to or larger than a threshold, the link state is restored to a normal mode from the sniff mode in a step S7. Counting of a timer is started in a step S8, and command transmission processing is executed in a step S10 in response to reception of user's operation input in a step S9, and a command is transmitted without a time lag. When it is judged in a step S11 that a time Tb has passes without receiving user's operation input, the link state is switched from the normal mode to the sniff mode in a step S12. This invention is applicable to a remote commander. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an information processing device, an information processing method, and a program, and is particularly suitable for use in a device that requires immediate responsiveness such as a remote commander to reduce power consumption in communication processing. The present invention relates to an information processing apparatus, an information processing method, and a program.
[0002]
[Prior art]
In particular, in a portable device that is supplied with power by a battery pack or the like, it is easy to carry in order to increase the convenience of the user by extending the life of the battery as much as possible or downsizing the battery pack. In order to do so, it is required to reduce power consumption.
[0003]
Conventionally, for example, in a mobile phone that operates with a battery voltage supplied from a battery pack and can be used without being held by hand when using the earphone microphone, the presence / absence of use of the earphone microphone is detected, and the detection result is determined Thus, while the earphone microphone is being used, the power of the transmission signal can be adjusted, and the power of the transmission signal is reduced below the prescribed power specified in advance. A technique is sometimes used in which the consumption time of the charging voltage in the battery pack is reduced so that the operation time operable with the battery voltage supplied from the battery pack can be extended (for example, see Patent Document 1). .
[0004]
[Patent Document 1]
JP 2003-60515 A
[0005]
Conventionally, in an information processing apparatus capable of performing communication by Bluetooth, in order to reduce power consumption required for communication, a park mode, a hold mode, and a sniff mode are changed from a normal connection state. Thus, it is possible to shift to the three types of low power consumption modes.
[0006]
Park mode is a mode in which only the slave device can make a transition. The slave in this mode maintains synchronization with the piconet, that is, synchronization with the hopping pattern and the master clock, but exchanges packets with the master device. I can't do it. The slave in this state receives data from the master at regular intervals (beacon period), and can join the piconet as soon as necessary. In the park mode, the slave device once returns a slave identifier, which is a 3-bit address given from the master to the connected slave. Therefore, even if the slave desires to rejoin the piconet, it cannot be joined immediately if there is no free slave identifier assigned by the master. On the other hand, the master device gives an 8-bit park slave identifier to the slave entering the park mode instead of the slave identifier. The master can manage up to 255 parked slaves, and only the necessary slaves can join the piconet at any time.
[0007]
Also, the hold mode is a mode in which both the master and the slave can make transitions, so that transmission / reception is not performed during the set fixed period (hold time) while synchronizing with the piconet, and communication is resumed after the hold time. Has been made. While in hold mode, both master and slave can participate in other piconets.
[0008]
The sniff mode is a mode in which only the slave can transition, and is a mode in which information is transmitted and received at a constant interval (sniff interval) and power consumption is reduced during other times.
[0009]
Specifically, as shown in FIG. 1, the slave device becomes active only at a predetermined time Ton within the sniff interval Tsniff, enters the reception mode, and receives a packet addressed to itself. Data is transmitted as necessary, but other times Toff are inactive (sleep), so that packets that come during the suspension cannot be received.
[0010]
The sniff interval Tsniff and the time Ton that is in the active state are determined between the master and the slave, and can be changed midway.
[0011]
For example, when it is not necessary to perform communication, such as when there is no operation input from the user for a certain period of time, the power consumption for communication can be reduced by shifting the communication link state to the sniff mode. Has been made.
[0012]
[Problems to be solved by the invention]
However, in the conventionally used sniff mode, when a user's operation input is received in the sleep state, the state cannot be immediately restored to the normal communication mode, and the average return until the normal communication mode is restored. The time Tret is 1/2 of the sniff interval Tsniff (Tret = Tsniff / 2). In particular, as shown in FIG. 2, when an operation input from the user is made at a time T2 close to the time T1 when the active state is changed to the sleep state, the time until the time T3 when the user enters the active state after the operation input is made. The time lag Td is substantially the same as the sniff interval Tsniff.
[0013]
In other words, the longer the sniff interval Tsniff, the greater the amount of power consumption reduction, but the longer the average return time Tret, which impairs user convenience. This has been a factor that hinders the reduction in power consumption in a device such as a remote commander that is battery-driven but requires immediate response.
[0014]
Further, when the power consumption is controlled by detecting the use state of the user by using the technique described in Patent Document 1, an insertion detection terminal is provided on the pin of the earphone plug, and the earphone jack Since it is necessary to provide a detection terminal for detecting whether or not the earphone plug is inserted in correspondence with the insertion detection terminal, this has been a factor in increasing costs.
[0015]
The present invention has been made in view of such a situation, and is intended to satisfy the immediate response while reducing the power consumption by communication.
[0016]
[Means for Solving the Problems]
The information processing apparatus according to the present invention is based on an operation input unit that receives an input of an operation by a user, a communication unit that executes communication with another information processing apparatus, and whether or not the information processing apparatus is gripped by the user. Control means for controlling communication by the communication means, and the communication means includes a first communication mode in which communication with other information processing apparatuses is always possible, and a first time shorter than the first time among the first times. The communication means communicates with the other information processing apparatus in at least two communication modes, ie, the second communication mode capable of communicating with the other information processing apparatus only for two times, and the control means performs the second communication by the communication means. When it is detected that the information processing apparatus is gripped by the user during the execution of the mode, the communication by the communication unit is changed to the first communication mode, and during the execution of the first communication mode by the communication unit, You If not performed a predetermined time input operation by the communication by the communication unit, and changing the second communication mode.
[0017]
The communication means can be made to communicate wirelessly with other information processing devices using radio waves, and a value indicating the radio wave state can be acquired and supplied to the control means. The control means can be made to detect whether or not the information processing apparatus is gripped by the user by detecting a change in the radio wave condition based on the value indicating the radio wave condition supplied by the communication means.
[0018]
The control means can be made to calculate the amount of change in the value indicating the radio wave state supplied by the communication means in execution of the second mode, and the calculated value of the amount of change in the value indicating the radio wave state is predetermined. If it is larger than the threshold value, the communication by the communication means can be changed to the first communication mode.
[0019]
A storage means for storing a first change pattern that is a change pattern of a value indicating a radio wave state when the information processing apparatus is predicted to be gripped by a user can be further provided. When the second change pattern, which is a change pattern of the value indicating the radio wave state supplied by the communication means in execution of the second mode, matches the first change pattern stored in the storage means If it is determined, the communication by the communication means can be changed to the first communication mode.
[0020]
The second change pattern during execution of the second communication mode matches the first change pattern stored in the storage means, and the user's operation is input by the operation input means within a predetermined time. In this case, the storage unit can further store the second change pattern as a positive history, and the second change pattern during execution of the second communication mode is stored by the storage unit. If the user matches the first change pattern and the user does not input an operation with the operation input means within a predetermined time, the storage means further stores the second change pattern as a negative history. The control means further includes a process of updating the first change pattern stored in the storage means based on the positive history and the negative history stored in the storage means. It is possible to so as to control.
[0021]
The control means can be further provided with a measuring means for measuring the third time during which the first communication mode is executed and the fourth time during which the second communication mode is executed. Can further control the set values of the first time and the second time in the second communication mode based on the third time and the fourth time measured by the measuring means.
[0022]
The control unit includes the first communication unit in the second communication mode such that the longer the third time measured by the measurement unit, the longer the ratio of the second time to the first time in the second communication mode. It is possible to control the set values of the second time and the second time.
[0023]
The control means includes a first time in the second communication mode such that the longer the fourth time measured by the measurement means, the shorter the ratio of the second time to the first time in the second communication mode. It is possible to control the set values of the second time and the second time.
[0024]
In the information processing apparatus of the present invention, an operation is input by a user, communication with another information processing apparatus is executed, communication is controlled based on whether the information processing apparatus is gripped by the user, A first communication mode in which communication with an information processing device is always possible, and a second communication mode in which communication with other information processing devices is possible only during a second time shorter than the first time of the first time. Communication with another information processing apparatus in at least two communication modes, and when it is detected that the information processing apparatus is gripped by the user during execution of the second communication mode, the communication is The communication mode is changed to the first communication mode, and if the user does not perform an operation input for a predetermined time during the execution of the first communication mode, the communication is changed to the second communication mode.
[0025]
The information processing method of the present invention is grasped by the information processing apparatus by the user in the first communication mode in which communication with another information processing apparatus is possible only during a second time shorter than the first time in the first time. A determination step for determining whether or not the information processing device has been processed; and if the processing of the determination step determines that the information processing device is gripped by the user, the communication is performed in the second communication mode in which communication with other information processing devices is possible at all times And a transition step for transitioning the state.
[0026]
In the first communication mode in which the program of the present invention can communicate with another information processing apparatus only for a second time shorter than the first time in the first time, is the information processing apparatus held by the user? In the determination step for determining whether or not the information processing device is grasped by the user by the processing of the determination step, the communication state is set to the second communication mode in which communication with other information processing devices is possible at all times And a transition step for transitioning.
[0027]
In the information processing method and the program according to the present invention, information processing by the user is performed in the first communication mode in which communication with another information processing apparatus is possible only during a second time shorter than the first time. When it is determined whether or not the apparatus has been gripped, and it is determined that the information processing apparatus has been gripped by the user, the communication state is shifted to the second communication mode in which communication with other information processing apparatuses is always possible. .
[0028]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below. In order to clarify the correspondence between each means and each step of the invention described in the claims and the following embodiments, each means and each step will be described. The features of the present invention are described as follows by adding the corresponding embodiment (however, by way of example) within the parentheses. However, of course, this description does not mean that each means and each step are limited to those described.
[0029]
The information processing apparatus according to claim 1 (for example, the remote commander 1 in FIG. 3) includes an operation input unit (for example, the input unit 13 in FIG. 4) that receives an operation input by the user, and another information processing apparatus (for example, the remote commander 1 in FIG. 3). , Communication means (for example, the Bluetooth module 12 in FIG. 4) for executing communication with the television receiver 2) in FIG. 3 and communication by the communication means based on whether or not the information processing apparatus is gripped by the user. Control means (for example, the CPU 11 in FIG. 4) for controlling, and the communication means is configured to be capable of always communicating with other information processing apparatuses in a first communication mode (for example, a normal mode) and a first time (for example). For example, in the sniff interval, the second communication mode (for example, communication with other information processing apparatuses can be performed only for the second time (for example, the time Ton in the active state in FIG. 5) shorter than the first time). The communication means communicates with another information processing apparatus in at least two communication modes (sniff mode), and the control means indicates that the information processing apparatus is grasped by the user during execution of the second communication mode by the communication means. If detected, the communication by the communication means is changed to the first communication mode, and no operation input is performed by the user for a predetermined time (for example, time Tb) during execution of the first communication mode by the communication means. In this case, the communication by the communication means is changed to the second communication mode.
[0030]
The information processing apparatus according to claim 2, wherein the communication unit communicates with another information processing apparatus wirelessly using radio waves, acquires a value (for example, RSSI) indicating a radio wave state, and transmits the value to the control unit. And the control unit detects a change in the radio wave state based on a value indicating the radio wave state supplied by the communication unit, and determines whether or not the information processing apparatus is gripped by the user. .
[0031]
The information processing apparatus according to claim 4 stores a first change pattern (for example, a change pattern P0) that is a change pattern of a value indicating a radio wave state when the information processing apparatus is predicted to be held by a user. Storage means (for example, the storage unit 15 in FIG. 4), and the control means is a second change pattern that is a change pattern of a value indicating the radio wave state supplied by the communication means in execution of the second mode. When it is determined that (for example, the change pattern P1) matches the first change pattern stored by the storage unit, the communication by the communication unit is changed to the first communication mode. To do.
[0032]
The information processing apparatus according to claim 5, wherein the second change pattern during execution of the second communication mode matches the first change pattern stored in the storage unit and is within a predetermined time. When a user operation is input by the operation input unit, the storage unit further stores the second change pattern as a positive history, and the second change pattern during execution of the second communication mode is stored by the storage unit. When the first change pattern matches with the stored first change pattern and the user does not input an operation with the operation input means within a predetermined time (for example, time Tb), the storage means displays the second change pattern. The negative change history is further stored, and the control means further controls the process of updating the first change pattern stored in the storage means based on the positive history and the negative history stored in the storage means. Characterized in that it.
[0033]
The information processing apparatus according to claim 6, wherein the third time during which the first communication mode is executed (for example, the time measured by the fourth timer in the process of FIG. 9), and the second communication It further comprises measuring means (for example, timer 16 in FIG. 4) for measuring a fourth time during which the mode is executed (for example, time measured in the second timer in the process of FIG. 9). Based on the third time and the fourth time measured by the measuring means, the set values of the first time and the second time in the second communication mode are further controlled.
[0034]
The information processing method according to claim 9 is used by being held by a user and performs processing for exchanging information with another information processing apparatus (for example, the television receiver 2 in FIG. 3) (for example, the information processing apparatus). 3 is an information processing method of the remote commander 1) in FIG. 3, and the second time (for example, the time Ton of the active state in FIG. 5) shorter than the first time in the first time (for example, the sniff interval). ) Only in a first communication mode (for example, sniff mode) in which communication with another information processing apparatus is possible, it is determined whether or not the information processing apparatus is held by the user (for example, steps S4 to S4 in FIG. 6). S6, step S34 and step S35 of FIG. 7, or the processing of step S64 to step S66 of FIG. When it is determined that the information processing apparatus has been gripped, a transition step (for example, FIG. 5) that transitions the communication state to the second communication mode (for example, the normal mode) in which communication with other information processing apparatuses is always possible. 6 step S7, step S36 in FIG. 7, or step S67 in FIG. 9).
[0035]
In the program according to claim 10, the embodiment (however, an example) to which each step corresponds is the same as the information processing method according to claim 9.
[0036]
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0037]
FIG. 3 is a diagram illustrating an example of a wireless communication system to which the present invention is applied.
[0038]
The remote commander 1 includes, for example, an input device such as a button, a key, a jog dial, or a touch panel, a display unit that displays predetermined text, thumbnails, and the like. A command indicating a user operation input is transmitted to the television receiver 2 and a control signal or the like is received from the television receiver 2 via Bluetooth.
[0039]
In addition to the television receiver 2 in FIG. 1, for example, a remote commander 2 such as a video deck, an audio player, or an air controller is used as an information processing apparatus that exchanges signals with the remote commander 1 using Bluetooth. Any device that allows the user to perform operation input may be used.
[0040]
FIG. 4 is a block diagram showing the internal configuration of the remote commander 1.
[0041]
The CPU 11 generates a command to be transmitted to the television receiver 2 based on the user operation input supplied from the input unit 13 and supplies the command to the Bluetooth module 12 or the user operation input supplied from the input unit 13. Alternatively, based on the control signal received from the television receiver 2 supplied from the Bluetooth module 12, information to be displayed on the display unit 14 is generated and displayed on the display unit 14. The CPU 11 can control the timer 16 to measure a predetermined time.
[0042]
The input unit 13 is configured by an input device such as a button, a key, a jog dial, or a touch panel, for example, and receives an operation input from the user and supplies it to the CPU 11. The display unit 14 includes, for example, an LED (Light Emitting Diode) or an LCD (Liquid Crystal Display), and displays information supplied from the CPU 11.
[0043]
The Bluetooth module 12 communicates information with the television receiver 2 via Bluetooth. A command supplied from the CPU 11 is transmitted to the television receiver 2 or transmitted from the television receiver 2. A control signal is supplied to the CPU 11. Communication between the Bluetooth module 12 and the CPU 11 is performed by transmitting and receiving an HCI (Host Controller Interface) command and an HCI event defined in the specification. The HCI is an interface that defines communication between the Bluetooth module 12 that is a communication module and the CPU 11 that is a host. In Bluetooth, commands for controlling the module from the host, links with other Bluetooth devices, There are prepared packet types of events for notifying the host of the status and information actually transmitted / received (for example, various control signals).
[0044]
Further, the Bluetooth module 12 may detect RSSI (Receive Signal Strength Indication), which is a value indicating a radio wave state of a communication link with the television receiver 2, according to a command supplied from the CPU 11, and supply it to the CPU 11. it can.
[0045]
Since the antenna for communication with the Bluetooth module 12 has directivity, the remote commander 1 placed in a stable place such as on a desk and not being held by the user is operated by the user. If the user grips and lifts the signal before being performed, the radio wave state of the communication link with the television receiver 2 changes. In other words, when the radio wave state of the communication link changes, it can be determined that there is a possibility of being grasped and input by the user.
[0046]
Upon receiving the HCI event from the Bluetooth module 12, the CPU 11 acquires information indicating the current state of the Bluetooth module 12 such as RSSI that is a value indicating the radio wave state of the communication link, and stores this information in the storage unit 15. save. The CPU 11 displays necessary information on the display unit 14 based on the current state of the Bluetooth module 12 and the user's operation input supplied from the input unit 13 or sends an HCI command to the Bluetooth module 12. Issue.
[0047]
The storage unit 15 receives supply of information necessary for processing of the CPU 11 including information indicating the state of the Bluetooth module 12, such as a value RSSI indicating the radio wave state, and stores the information.
[0048]
The timer 16 measures a predetermined time based on the control of the CPU 11. Further, the timer 16 may measure a plurality of times.
[0049]
Further, a drive 17 is connected to the CPU 11 as necessary. A magnetic disk 21, an optical disk 22, a magneto-optical disk 23, or a semiconductor memory 24 is mounted on the drive 17 so that information can be exchanged.
[0050]
In the remote commander 1, when the mode of communication with the television receiver 2 transitions from the normal mode to the sniff mode, the Bluetooth module 12 indicates that the mode of communication with the television receiver 2 is the sniff mode with respect to the CPU 11. “HCI_MODE_CHANGE_EVENT”, which is an event for notifying the user, is supplied.
[0051]
When the CPU 11 detects that the communication mode with the television receiver 2 is the sniff mode based on the HCI event supplied from the Bluetooth module 12, the CPU 11 periodically receives the television image from the Bluetooth module 12. An “HCI_READ_RSSI” command, which is a command for obtaining a value RSSI indicating a radio wave state of a communication link with the machine 2, is issued. Then, the CPU 11 receives the supply of “HCI_COMMAND_COMPLETE_EVENT”, which is an event for notifying the value RSSI indicating the radio wave state, by executing a command from the Bluetooth module 12, acquires the value RSSI indicating the radio wave state, and the storage unit 15 to store a predetermined number.
[0052]
Then, the CPU 11 refers to the value RSSI indicating the radio wave state stored in the storage unit 15 and, for example, indicates whether or not the amount of change in the value RSSI indicating the radio wave state is greater than a predetermined value, or indicates the radio wave state. It is determined whether or not the remote commander 1 may be held by the user by determining whether or not the change pattern of the value RSSI matches a predetermined pattern and detecting a change in the radio wave state. To do. If the CPU 11 determines that there is a possibility that the user has grasped based on the detection result of the radio wave state, the command “HCI_EXIT_SNIFF_MODE” is a command for returning the mode of communication with the television receiver 2 from the sniff mode to the normal mode. ”Command to the Bluetooth module 12. Based on the command supplied from the CPU 11, the Bluetooth module 12 returns the mode of communication with the television receiver 2 from the sniff mode to the normal mode and is an event “HCI_COMMAND_COMPLETE_EVENT” for notifying that the command has been executed. Is supplied to the CPU 11.
[0053]
When the CPU 11 receives a user's operation input continuously within a predetermined time in the normal mode, the CPU 11 continues the communication mode with the television receiver 2 in the normal mode. When there is no user operation input, an “HCI_SNIFF_MODE” command for changing the mode of communication with the television receiver 2 from the normal mode to the sniff mode is issued to the Bluetooth module 12. Based on the command supplied from the CPU 11, the Bluetooth module 12 changes the mode of communication with the television receiver 2 to the sniff mode and notifies the CPU 11 of “HCI_MODE_CHANGE_EVENT”, which is an event for notifying that the command has been executed. To supply.
[0054]
In this way, the remote commander 1 to which the present invention is applied can detect a change in radio wave state and can change the state to a normal link state. Therefore, in the conventional case shown in FIG. 5A, the present invention is applied to the time lag Td that occurs from the time T12 at which the operation input from the user is received to the time T13 at which communication becomes active. As shown in FIG. 5B, the remote commander 1 detects the change in the radio wave state due to the operation of the user lifting the remote commander at time T11 before the operation input. At T12, the normal link state has already been established. Therefore, in the remote commander 1 to which the present invention is applied, it is possible to immediately respond to a user's operation input without causing a time lag.
[0055]
Further, whether or not there is a possibility that the user has held the remote commander 1 may be detected using, for example, a touch sensor, but a change in the radio wave state is detected and the detection result is used as a basis. Since it is possible to determine whether or not there is a possibility that the user has held the remote commander 1, it is not necessary to use a dedicated sensor or the like. It is possible to achieve the purpose of determining whether or not there is a possibility of gripping.
[0056]
Next, the link state control process 1 executed by the remote commander 1 will be described with reference to the flowchart of FIG.
[0057]
In step S1, the CPU 11 of the remote commander 1 determines whether or not “HCI_MODE_CHANGE_EVENT”, which is an event for notifying that the mode of communication with the television receiver 2 has been changed to the sniff mode, has been supplied from the Bluetooth module 12. Based on the above, it is determined whether or not the link state is in the sniff mode. If it is determined in step S1 that the link state is not in the sniff mode, the process in step S1 is repeated until it is determined that the link state is in the sniff mode.
[0058]
If it is determined in step S1 that the link state has become the sniff mode, the CPU 11 starts counting the timer 16 in step S2.
[0059]
In step S3, the CPU 11 refers to the count of the timer 16 and determines whether or not a predetermined time Ta has elapsed since the transition to the sniff mode. If it is determined in step S3 that the predetermined time Ta has not elapsed since the transition to the sniff mode, the process of step S3 is repeated until it is determined that the predetermined time Ta has elapsed. Here, the predetermined time Ta is a time interval for issuing an HCI command for causing the Bluetooth module 12 to acquire a value RSSI indicating a radio wave state, and a change in the radio wave state due to an operation in which the user holds the remote commander 1. A time interval short enough to be detected is set.
[0060]
When it is determined in step S3 that the predetermined time Ta has elapsed, in step S4, the CPU 11 clears the count of the timer 16 and also transmits a link for communication with the television receiver 2 to the Bluetooth module 12. An “HCI_READ_RSSI” command for obtaining the value RSSI indicating the radio wave state is issued, the supply of “HCI_COMMAND_COMPLETE_EVENT” is received from the Bluetooth module 12, the value RSSI indicating the radio wave state is acquired and stored in the storage unit 15. When the storage unit 15 is newly supplied with the value RSSI indicating the radio wave condition, the storage unit 15 is configured to sequentially delete old information, and the value RSSI indicating a predetermined number of new radio wave conditions is always stored. It is made like that.
[0061]
In step S <b> 5, the CPU 11 calculates the amount of change in the radio wave state by, for example, subtraction processing based on the value RSSI indicating the radio wave state of the past communication link stored in the storage unit 15.
[0062]
In step S6, the CPU 11 determines whether or not the amount of change in the radio wave state is equal to or greater than a predetermined threshold value. Here, the predetermined threshold is a predetermined value determined experimentally or empirically, and is stored in advance in the storage unit 15, for example. If it is determined in step S6 that the amount of change in the radio wave state is not equal to or greater than a predetermined threshold value, the process returns to step S2 and the subsequent processes are repeated.
[0063]
If it is determined in step S6 that the amount of change in the radio wave state is equal to or greater than a predetermined threshold value, in step S7, the CPU 11 changes the mode of communication with the television receiver 2 from the sniff mode to the normal mode. An “HCI_EXIT_SNIFF_MODE” command, which is a command for returning, is issued to the Bluetooth module 12 to return the link state to the normal mode. Based on the command supplied from the CPU 11, the Bluetooth module 12 returns the mode of communication with the television receiver 2 from the sniff mode to the normal mode, and “HCI_COMMAND_COMPLETE_EVENT” is an event for notifying that the command has been executed. Is supplied to the CPU 11.
[0064]
In step S8, the CPU 11 starts counting the timer 16, and in step S9, determines whether or not a user operation input has been received based on a signal supplied from the input unit 13.
[0065]
When it is determined in step S9 that the user's operation input has been received, in step S10, the CPU 11 clears the count of the timer 16, and based on the signal indicating the user's operation input supplied from the input unit 13. The command transmission process for the television receiver 2, that is, the command corresponding to the user's operation input is generated, supplied to the Bluetooth module 12 and transmitted to the television receiver 2, and the process Returning to S8, the subsequent processing is repeated.
[0066]
In the process of step S10, since the link state is the normal mode, a command corresponding to the user's operation input can be transmitted to the television receiver 2 without a time lag.
[0067]
If it is determined in step S9 that no user operation input has been received, in step S11, the CPU 11 refers to the timer 16 and a predetermined time Tb has elapsed since the link state returned to the normal mode. Determine whether or not. Here, the predetermined time Tb is a time set in advance so that the communication link state is changed to the sniff mode when the user's operation input is not received for that time. If it is determined in step S11 that the predetermined time Tb has not elapsed, the process returns to step S9, and the subsequent processes are repeated.
[0068]
When it is determined in step S11 that the predetermined time Tb has elapsed, in step S12, the CPU 11 executes an “HCI_SNIFF_MODE” command for changing the mode of communication with the television receiver 2 from the normal mode to the sniff mode. , The communication link state is changed to the sniff mode by issuing to the Bluetooth module 12, and the Bluetooth module 12 changes the communication mode with the television receiver 2 to the sniff mode based on the command supplied from the CPU 11. The CPU 11 is supplied with “HCI_MODE_CHANGE_EVENT”, which is an event for notifying that it has been made. After the process of step S12 is completed, the process returns to step S2, and the subsequent processes are repeated.
[0069]
By such processing, a change in the radio wave state that occurs when the user grips the device is detected, and the communication link state is changed from the sniff mode to the normal mode. The link state can be set to the sniff mode so that power consumption can be reduced and an immediate response can be made to the user's operation input.
[0070]
In the processing described with reference to FIG. 6, it has been described that the normal mode is restored when the amount of change in the radio wave state value is greater than a predetermined threshold. However, for example, the remote commander 1 and the television are used. Even if a person or an object passes between the receiver 2 and the receiver 2, there is a possibility that a change in the radio wave state may be detected. There is a possibility that the link state of the communication is changed to the normal mode. In such a case, it is possible to immediately respond to the user's operation input, but the power consumption reduction efficiency may be lowered.
[0071]
In order to detect a change in the radio wave state based on a predetermined operation such as when the user lifts the remote commander 1, for example, the radio wave state detected when an operation input is actually performed by the user. The reference change pattern may be stored in the storage unit 15 as the change pattern P0. Then, by comparing the change pattern P1 of the value RSSI indicating the current radio wave state with the stored change pattern P0, the radio wave state change based on a predetermined operation, such as when the user lifts the remote commander 1 Can be detected.
[0072]
Next, the link state control processing 2 for controlling the link state by comparing the change patterns of the radio wave state will be described with reference to the flowcharts of FIGS.
[0073]
In steps S31 to S34, the same processing as in steps S1 to S4 in FIG. 6 is executed.
[0074]
That is, when it is determined that the link state has transitioned to the sniff mode, the timer starts counting, and when it is determined that the predetermined time Ta has elapsed, the value RSSI indicating the radio wave state is acquired.
[0075]
Here, since the value RSSI indicating the predetermined number of new radio wave conditions is always stored in the storage unit 15, the value RSSI indicating the radio wave condition acquired in step S34 and the stored radio wave condition are indicated. By using the value RSSI, the current radio wave state change pattern P1 can be obtained.
[0076]
Therefore, in step S35, the CPU 11 determines whether or not the radio wave state change pattern P1 matches the change pattern P0 stored in the storage unit 15 that is updated by the process in step S44 described later. If it is determined in step S35 that the change pattern P1 and the change pattern P0 do not match, the process returns to step S32, and the subsequent processes are repeated.
[0077]
Here, the matching can be performed using, for example, a least square method. Note that any method other than the method of least squares may be used for the matching process. Further, in the state where the change pattern P0 is not stored in the storage unit 15, the change pattern P1 may be processed unconditionally as being matched with the change pattern P0.
[0078]
If it is determined in step S35 that the change pattern P1 and the change pattern P0 match, the same processing as in steps S7 to S10 described with reference to FIG. 6 is executed in steps S36 to S39.
[0079]
That is, when the communication link state is returned to the normal mode, the timer starts counting, and it is determined that the user's operation input is received, command transmission processing for the television receiver 2 is executed.
[0080]
After the process of step S39 is completed, in step S40, the CPU 11 stores the change pattern P1 determined to be matched with the change pattern P0 in step S35 in the storage unit 15 as a positive history, and the process proceeds to step S37. Return, and the subsequent processing is repeated.
[0081]
That is, when it is determined in step S38 that the user's operation input has been received, the change pattern P1 determined to match the change pattern P0 in step S35 is the radio wave state generated because the remote commander 1 is lifted by the user. Therefore, the radio wave state change pattern P1 is stored in the storage unit 15 as a positive history and used as learning information when the change pattern P0 is updated.
[0082]
When it is determined in step S38 that the user's operation input has not been received, in step S41, the CPU 11 refers to the timer 16 and a predetermined time Tb has elapsed since the link state has returned to the normal mode. Determine whether or not. If it is determined in step S41 that the predetermined time Tb has not elapsed, the process returns to step S38, and the subsequent processes are repeated.
[0083]
If it is determined in step S41 that the predetermined time Tb has elapsed, in step S42, the CPU 11 stores the change pattern P1 determined to be matched with the change pattern P0 in step S35 as a negative history in the storage unit 15. Remember.
[0084]
That is, when it is determined in step S41 that the predetermined time Tb has elapsed, no operation input is performed by the user, so the change pattern P1 determined to match the change pattern P0 in step S35 is changed by the user. There is a high possibility that the radio wave state change pattern generated when the remote commander 1 is lifted is different. Therefore, when a change pattern similar to this change pattern P1 occurs, it is predicted that no operation input from the user will be received even if the link state is returned to the normal mode. Therefore, this radio wave state change pattern P1 Is stored in the storage unit 15 as a negative history and used as learning information when the change pattern P0 is updated.
[0085]
In step S43, the CPU 11 issues an “HCI_SNIFF_MODE” command for changing the mode of communication with the television receiver 2 from the normal mode to the sniff mode to the Bluetooth module 12, thereby changing the communication link state to the sniff mode. Based on the command supplied from the CPU 11, the Bluetooth module 12 sends “HCI_MODE_CHANGE_EVENT”, which is an event for notifying that the mode of communication with the television receiver 2 has been changed to the sniff mode, to the CPU 11. To supply.
[0086]
In step S44, the CPU 11 updates the radio wave state change pattern P0 based on the positive history stored by the process of step S40 and the negative history stored by the process of step S42. That is, the CPU 11 generates and updates the radio wave state change pattern P0 that is similar to the radio wave state change pattern that is a positive history and that is not similar to the radio wave state change pattern that is a negative history. After the process of step S44 is completed, the process returns to step S32, and the subsequent processes are repeated.
[0087]
By such processing, the reference radio wave state change pattern P0 is updated by learning, so that the radio wave state change pattern generated when the remote commander 1 is lifted by the user can be accurately detected. Thereby, for example, it is possible to prevent the communication link state from being returned to the normal mode due to a change in radio wave state when a person or an object passes between the remote commander 1 and the television receiver 2. Therefore, it is possible to reduce power consumption more efficiently without reducing the immediate response to the user's operation.
[0088]
Here, the radio wave state change pattern serving as a positive history and the radio wave state change pattern serving as a negative history have been described as updating the radio wave state change pattern P0 serving as a reference. The change pattern P0 of the state may be obtained experimentally or empirically in advance and stored in the storage unit 15, and the change of the radio wave state may always be detected by using this change pattern P0.
[0089]
Further, the CPU 11 of the remote commander 1 adjusts the sniff interval based on whether or not the operation by the user is frequently performed, and changes the time Ton and the time Toff in FIG. The power consumption can be reduced more efficiently without reducing the responsiveness.
[0090]
Next, the link state control process 3 in the case where the sniff interval is adjusted based on whether or not the operation by the user is frequently performed will be described with reference to the flowchart of FIG. Here, description will be made on the assumption that the timer 16 can measure four different types of time by incorporating a first timer to a fourth timer.
[0091]
In step S61, whether or not the CPU 11 of the remote commander 1 has received an event “HCI_MODE_CHANGE_EVENT”, which is an event for notifying the Bluetooth module 12 that the mode of communication with the television receiver 2 has been changed to the sniff mode. Based on the above, it is determined whether or not the link state is in the sniff mode. If it is determined in step S1 that the link state is not in the sniff mode, the process in step S61 is repeated until it is determined that the link state is in the sniff mode.
[0092]
If it is determined in step S61 that the link state is in the sniff mode, the CPU 11 starts counting the first timer and the second timer of the timer 16 in step S62.
[0093]
In step S63, the CPU 11 refers to the count of the first timer of the timer 16 and determines whether or not a predetermined time Ta has elapsed since the transition to the sniff mode. If it is determined in step S63 that the predetermined time has not elapsed since the transition to the sniff mode, the process of step S63 is repeated until it is determined that the predetermined time Ta has elapsed.
[0094]
When it is determined in step S63 that the predetermined time Ta has elapsed, in step S64, the CPU 11 clears the count of the first timer of the timer 16 and also transmits the television receiver 2 to the Bluetooth module 12. The command “HCI_READ_RSSI”, which is a command for obtaining the value RSSI indicating the radio wave state of the communication link, is issued. And stored in the storage unit 15.
[0095]
In step S <b> 65, the CPU 11 calculates the amount of change in the radio wave state by, for example, subtraction processing based on the value RSSI indicating the radio wave state of the past communication link stored in the storage unit 15.
[0096]
In step S66, the CPU 11 determines whether or not the amount of change in the radio wave state is greater than or equal to a predetermined threshold value. If it is determined in step S6 that the amount of change in the radio wave state is not greater than or equal to a predetermined threshold value, the process returns to step S62, and the subsequent processes are repeated.
[0097]
If it is determined in step S66 that the amount of change in the radio wave state is equal to or greater than a predetermined threshold value, in step S67, the CPU 11 changes the mode of communication with the television receiver 2 from the sniff mode to the normal mode. An “HCI_EXIT_SNIFF_MODE” command, which is a command for returning, is issued to the Bluetooth module 12 to return the link state to the normal mode, and the storage unit 15 stores the count value of the second timer of the timer 16. . Based on the command supplied from the CPU 11, the Bluetooth module 12 returns the mode of communication with the television receiver 2 from the sniff mode to the normal mode, and “HCI_COMMAND_COMPLETE_EVENT” is an event for notifying that the command has been executed. Is supplied to the CPU 11.
[0098]
Since the count value of the second timer is a value corresponding to the time when the communication is executed in the sniff mode, it correlates with the time until it is detected that the user holds the remote commander after the transition to the sniff mode. Value. That is, the count value of the second timer is a value that correlates with a time shorter than the time when the user does not perform an operation input after the transition to the sniff mode.
[0099]
In step S68, the CPU 11 starts counting the third timer of the timer 16, and if the counting of the fourth timer of the timer 16 has not started, starts counting and starts counting. In this case, the counting is continued, and it is determined in step S69 whether or not a user operation input has been received based on the signal supplied from the input unit 13.
[0100]
If it is determined in step S69 that the user's operation input has been received, in step S70, the CPU 11 clears the count of the third timer of the timer 16 and receives the user's operation input supplied from the input unit 13. Based on the signal shown, command transmission processing for the television receiver 2, that is, processing for generating a command corresponding to a user operation input, supplying the command to the Bluetooth module 12, and transmitting the command to the television receiver 2 is executed. The processing returns to step S68, and the subsequent processing is repeated.
[0101]
In the process of step S70, since the link state is the normal mode, a command corresponding to the user's operation input can be transmitted to the television receiver 2 without a time lag.
[0102]
When it is determined in step S69 that the user's operation input is not received, in step S71, the CPU 11 refers to the count value of the third timer of the timer 16 and the link state returns to the normal mode. It is determined whether or not a predetermined time Tb has elapsed. If it is determined in step S71 that the predetermined time Tb has not elapsed, the process returns to step S69, and the subsequent processes are repeated.
[0103]
If it is determined in step S71 that the predetermined time Tb has elapsed, in step S72, the CPU 11 calculates the sniff interval based on the count value of the second timer and the count value of the fourth timer of the timer 16. Then, the setting is changed and the mode of communication with the television receiver 2 is changed from the normal mode to the sniff mode.
[0104]
The count value of the fourth timer is a value corresponding to the time when the communication link state is the normal mode, and when the user performs an operation input continuously within a predetermined time, the count value of the fourth timer The count value increases. As described above, the count value of the second timer is a value that correlates with a time shorter than the time when the user does not perform the operation input after the transition to the sniff mode. Therefore, when the count value of the fourth timer is large, the operation input is frequently performed by the user, and when the count value of the second timer is large, it is predicted that the operation input is not performed by the user so much. Can do.
[0105]
Specifically, based on the count value of the second timer and the count value of the fourth timer of the timer 16, the CPU 11 increases the sniff interval as the second count value increases. A process for calculating and setting the sniff interval so that the larger the count value of 4, the shorter the sniff interval, and for causing the television receiver 2 to notify the newly calculated and changed sniff interval. The Bluetooth module 12 is executed.
[0106]
In calculating the sniff interval, a minimum value or maximum value, or a minimum value and a maximum value are set in advance so that the calculated sniff interval does not become less than the minimum value or does not become more than the maximum value. Anyway. In addition to adjusting the ratio of the active state time Ton to the sniff interval by adjusting the sniff interval with the active state time Ton in the sniff mode constant, for example, the sniff interval is constant and the active state time Ton may be changed, and both the sniff interval and the active state time Ton may be changed.
[0107]
Further, the CPU 11 issues the “HCI_SNIFF_MODE” command for changing the mode of communication with the television receiver 2 from the normal mode to the sniff mode to the Bluetooth module 12, thereby changing the communication link state to the sniff mode. The Bluetooth module 12 supplies “HCI_MODE_CHANGE_EVENT”, which is an event for notifying that the mode of communication with the television receiver 2 has been changed to the sniff mode based on the command supplied from the CPU 11. To do. After the process of step S72 is completed, the process returns to step S62, and the subsequent processes are repeated.
[0108]
By such a process, when the user's operation is performed to some extent frequently, the sniff interval is shortened, and when the user's operation is not performed so much, the sniff interval is increased. Since the sniff interval can be adjusted, the power consumption can be reduced more efficiently without reducing the immediate response to the user's operation.
[0109]
In the process of FIG. 9, the link state is returned to the normal mode based on whether or not the amount of change in the radio wave state is equal to or greater than a predetermined threshold. However, for example, FIG. 7 and FIG. It goes without saying that it may be determined whether or not to return the link state to the normal mode by comparing the change patterns of the radio wave state in the same manner as described with reference to FIG.
[0110]
In the processing described with reference to FIGS. 6 to 9, it is possible to detect that the user lifted the remote commander 1 by detecting a change in the radio wave state, and to change the operation mode to the normal mode. As described above, the method for detecting that the user lifted the remote commander 1 may be a method other than the change in the radio wave state. For example, whether or not the user has touched the remote commander 1 with a touch sensor or the like. It may be possible to determine whether the user has lifted the remote commander by detecting a change in electric field strength or a change in the link state of wireless communication. Thus, the operation mode may be controlled.
[0111]
Further, in the above description, in the Bluetooth sniff mode, it is detected that the user lifts the remode commander 1, and the operation mode is changed to the normal mode, thereby maintaining the immediate response and reducing the power consumption. Although it has been described that it can be reduced, for example, in any communication method other than Bluetooth, the communication state is made active every predetermined period by the same processing as in the sniff mode described above, and other than that In this period, the present invention can be applied when the power consumption by communication can be reduced in the sleep state.
[0112]
In the above description, the remote commander 1 to which the present invention is applied has been described. However, the present invention is an apparatus that can communicate with other apparatuses and can detect a predetermined operation such as being grasped by a user. It is possible to apply.
[0113]
The series of processes described above can also be executed by software. The software is a computer in which a program constituting the software is incorporated in dedicated hardware, or a various personal computer capable of executing various functions by installing various programs. For example, it is installed from a recording medium.
[0114]
As shown in FIG. 4, this recording medium is distributed to provide a program to a user separately from a computer, and includes a magnetic disk 21 (including a flexible disk) on which a program is recorded, an optical disk 22 (CD- Consists of a package medium including a ROM (compact disk-read only memory), a DVD (digital versatile disk), a magneto-optical disk 23 (including MD (mini-disk) (trademark)), or a semiconductor memory 24 Is done.
[0115]
Further, in the present specification, the step of describing the program recorded on the recording medium is not limited to the processing performed in time series according to the described order, but is not necessarily performed in time series. It also includes processes that are executed individually.
[0116]
In the present specification, the term “system” represents the entire apparatus constituted by a plurality of apparatuses.
[0117]
【The invention's effect】
Thus, according to the present invention, it is possible to communicate with other information processing apparatuses. In particular, since the communication mode can be controlled based on the detection result of whether or not the user has grasped, the power consumption can be effectively reduced while maintaining the immediate response.
[Brief description of the drawings]
FIG. 1 is a diagram for explaining a sniff mode.
FIG. 2 is a diagram for explaining a time lag that occurs in a sniff mode.
FIG. 3 is a diagram for explaining a radio communication system to which the present invention is applied.
4 is a block diagram showing the configuration of the remote commander of FIG. 3. FIG.
FIG. 5 is a diagram for explaining a conventional sniff mode and a sniff mode of a remote commander to which the present invention is applied.
FIG. 6 is a flowchart for explaining link state control processing 1;
FIG. 7 is a flowchart for explaining link state control processing 2;
FIG. 8 is a flowchart for explaining link state control processing 2;
FIG. 9 is a flowchart for explaining link state control processing 3;
[Explanation of symbols]
1 remote commander, 2 television receiver, 11 CPU, 12 Bluetooth module, 13 input unit, 14 display unit, 15 storage unit, 16 timer

Claims (10)

In an information processing apparatus that is gripped and used by a user,
An operation input means for receiving an input of an operation by the user;
Communication means for executing communication with other information processing apparatuses;
Control means for controlling communication by the communication means based on whether or not the information processing apparatus is gripped by the user,
The communication means includes a first communication mode in which communication with the other information processing apparatus is possible at all times, and a second time shorter than the first time among the first time. Communicate with the other information processing apparatus in at least two communication modes, the second communication mode capable of communicating with
When the control unit detects that the information processing apparatus is gripped by the user during the execution of the second communication mode by the communication unit, the control unit performs communication by the communication unit. When the user does not perform an operation input for a predetermined time during the execution of the first communication mode by the communication means, the communication by the communication means is changed to the second communication mode. An information processing apparatus characterized by: The communication unit communicates with the other information processing apparatus wirelessly using radio waves, acquires a value indicating a radio wave state, and supplies the value to the control unit,
The control unit detects a change in radio wave state based on a value indicating the radio wave state supplied by the communication unit, and determines whether or not the information processing apparatus is held by the user. The information processing apparatus according to claim 1. The control unit calculates a change amount of the value indicating the radio wave state supplied by the communication unit during execution of the second mode, and the calculated value of the change amount of the value indicating the radio wave state is a predetermined threshold value The information processing apparatus according to claim 2, wherein if larger, the communication by the communication unit is changed to the first communication mode. A storage unit that stores a first change pattern that is a change pattern of a value indicating a radio wave state when the information processing apparatus is predicted to be held by the user;
The control means stores the first change pattern, which is a change pattern of a value indicating the radio wave state supplied by the communication means during execution of the second mode, stored in the storage means. 3. The information processing apparatus according to claim 2, wherein if it is determined that the change pattern matches the communication pattern, the communication by the communication unit is changed to the first communication mode. The second change pattern during execution of the second communication mode matches the first change pattern stored in the storage means, and the user is input by the operation input means within a predetermined time. When the operation is input, the storage means further stores the second change pattern as a positive history,
The second change pattern during execution of the second communication mode matches the first change pattern stored in the storage means, and the user is input by the operation input means within a predetermined time. Does not input an operation, the storage means further stores the second change pattern as a negative history,
The control means further controls processing for updating the first change pattern stored in the storage means based on the positive history and the negative history stored in the storage means. The information processing apparatus according to claim 3. A measuring means for measuring a third time during which the first communication mode is executed and a fourth time during which the second communication mode is executed;
The control means further sets set values of the first time and the second time in the second communication mode based on the third time and the fourth time measured by the measuring means. The information processing apparatus according to claim 1, wherein the information processing apparatus is controlled. The control means is configured to increase the ratio of the second time to the first time in the second communication mode as the third time measured by the measuring means is longer. The information processing apparatus according to claim 6, wherein a set value of the first time and the second time in the communication mode is controlled. The control means is configured such that the longer the fourth time measured by the measuring means, the shorter the ratio of the second time to the first time in the second communication mode. The information processing apparatus according to claim 6, wherein a set value of the first time and the second time in the communication mode is controlled. In an information processing method of an information processing apparatus that is used by being held by a user and performs processing for exchanging information with another information processing apparatus,
Whether or not the information processing apparatus is held by the user in the first communication mode in which communication with the other information processing apparatus is possible only during a second time shorter than the first time in the first time. A determination step for determining
A transition step of transitioning the communication state to the second communication mode in which communication with the other information processing device is possible at all times when it is determined by the processing of the determination step that the information processing device is gripped by the user. An information processing method comprising: A program for causing a computer to execute processing for controlling transmission and reception of information with another information processing device by an information processing device held and used by a user,
Whether or not the information processing apparatus is held by the user in the first communication mode in which communication with the other information processing apparatus is possible only during a second time shorter than the first time in the first time. A determination step for determining
A transition step of transitioning the communication state to the second communication mode in which communication with the other information processing device is possible at all times when it is determined by the processing of the determination step that the information processing device is gripped by the user. The program characterized by including.

Images