JP2013255145A - Sensor terminal - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sensor terminal which stops or weakens transmission or reception in a non-detectable direction before being executed by an infrared ray transceiver which is disposed by changing its angle to expand a detection space.SOLUTION: The sensor terminal incorporates a plurality of infrared ray transceivers and an acceleration sensor, so that the sensor terminal detects by the infrared ray transceivers that it faces or is close to other terminals or transmitters by transmitting and receiving infrared ray data to and from them and detects their movement or inclination by the acceleration sensor. On the basis of the acceleration data obtained by the acceleration sensor, the sensor terminal controls part or all of the plurality of infrared ray transceivers.

Description

  The present invention relates to a system for acquiring face-to-face communication data between persons and visualizing the state of an organization, in particular, from a terminal that acquires and transmits a physical quantity with a sensor in such a system, and an infrared transmitter for detecting position information. Concerning the system.

  Conventionally, improvement of productivity has been an essential issue in all organizations, and many trials and errors have been made to improve the work environment and increase the efficiency of work. When the assembly or transportation of a factory or the like is limited to an organization that handles business, the process and results can be objectively analyzed by tracking the movement path of parts or products. On the other hand, regarding an organization composed of knowledge workers, there is already known an organization that visualizes business processes by using electronic documents instead of things and usage logs of IT devices.

  In the first place, an organization is formed in order to achieve large-scale work that cannot be done by individuals by combining multiple people. Therefore, in any organization, communication is always performed for decision making and agreement between two or more persons. Examples of communication means include telephone, fax, and e-mail. The communication that is most frequently performed and has the strongest influence is face-to-face communication. In face-to-face communication, you can make the most of the human body, such as gestures, gaze, facial expressions, and tone of voice. For this reason, many of the indispensable communications in an organization, such as the formation of a friendly relationship through daily greetings and the approaching of negotiations involving complicated profits, are naturally realized through face-to-face communication. .

  In face-to-face communication, two or more people involved create a conversation rhythm and atmosphere in real time. As a result, emotional resonance and the emergence of ideas can occur from places that cannot be predicted. There is a big part of the results of the creative ideas born in this way in the results of the organization centered on knowledge labor. The number of organizations that have become aware of its importance and have introduced attempts such as free seating for seats and organizing cross-sectional projects have been increasing in recent years. Both of these are expected to create new value by providing opportunities for people with diverse backgrounds to come into contact with each other.

Benjamin N. Waber, Daniel Olguin Olguin, Tamie Kim, Akshay Mohan, Koji Ara, and Alex (Sandy) Pentland, “Organic Engineering 7”.

  All of the conventional methods analyze work as the subject, but knowledge labor cannot be grasped without knowledge. This is because it is not possible to obtain the maximum result only by cutting out only the procedure and time for each work and aiming at efficiency improvement. Therefore, in order to bring out good results in knowledge labor, it is necessary to focus on individual characteristics, especially to know the work style. A work style is a pattern of how to proceed with personal work, when, where, and what to do. Work style reflects both the contents of work, which is an external factor, and the personality, which is an internal factor. Knowledge work professionals have established their own work styles. Some people get ideas while discussing, while others think alone. There are also people who go out and walk around, and those who sit at the desk and turn magazines, and the styles are diverse. As knowledge work is particularly spiritual, the method of achieving the most effect depends on the individual qualities and roles they play. However, conventional analysis methods mainly do not take into account the effects of matters that are not directly reflected in the work product, such as reading, walking, chatting, etc. Therefore, it is necessary to capture the work style by observing the actual behavior of each member based on the person. And by grasping and respecting each other's work styles, it is thought that the work style of the entire organization is established, leading to improved productivity.

  We have developed a system for visualizing and analyzing organizational activities to help improve the organization by detecting human movements and communication between people from the physical quantities obtained by these sensors, and visualizing the state of the organization.

  In the organizational activity visualization / analysis system, a terminal used to detect communication between people is a name tag type sensor terminal.

  The name tag type sensor terminal includes an acceleration sensor for detecting a feature of movement of the wearer, a microphone for detecting a feature of voice, a temperature sensor and an illuminance sensor for detecting temperature and brightness of the environment. Furthermore, in order to detect a person-to-person meeting, an infrared transceiver is provided. This infrared transmitter / receiver periodically transmits a unique ID and transmits / receives it between terminals, thereby detecting when a person has faced whom.

  For example, there is a UbER batch as a means for detecting a facing state by a terminal (Non-Patent Document 2). The size is 110x120mm and the weight is about 170g, and it can operate continuously for 15 hours.

  In the case of a prototype, there is no problem with the above specifications. However, when considering practical use, in order to detect human-human interaction using a terminal, it is necessary to be light and small enough that it does not cause pain even if worn for a long time. Therefore, since a small battery operates for a long time, the terminal must reduce wasteful power consumption.

  High-precision detection of face-to-face communication can be realized by a technique in which a plurality of infrared transmitters / receivers are mounted and arranged on a name tag type sensor terminal so that the transmission / reception angle of each infrared transmitter / receiver is expanded as a whole, and the infrared detection space is expanded. Face-to-face detection using infrared rays is based on infrared communication with each infrared transceiver worn by another person because the name-tag type sensor terminal hangs from the neck, is located on the body near the chest, and faces forward.

  However, by arranging so that the transmission / reception angle of each infrared transmitter / receiver spreads as a whole, the detection space is expanded when the name tag type sensor terminals are in front of each other, for example, when the name tag type sensor terminal tilts upward, The infrared transmitter / receiver arranged in the upward direction is turned upward more than usual, and the infrared ID transmitted by another name tag type sensor terminal or infrared transmitter cannot be received. In this case, the infrared transmitter / receiver arranged upward in the name tag type sensor terminal consumes extra power by performing an unnecessary operation. The name tag type sensor terminal is a terminal that requires a low power consumption operation because of a reduction in battery capacity for miniaturization and a continuous operation for a long time by one charge. For this reason, unnecessary power consumption must be reduced to a maximum.

  An object of the present invention is to perform a low power consumption operation by controlling infrared transmission / reception with respect to a plurality of infrared transceivers arranged at different angles in order to expand a detection space in a name tag type sensor terminal.

  The above-described problem is that a plurality of infrared transceivers and acceleration sensors are mounted, infrared data is transmitted / received to / from other terminals and transmitters by the infrared transceivers, and it is detected that they are facing each other or close to each other. A sensor terminal for detecting movement and tilt, wherein a part or all of a plurality of infrared transceivers are controlled based on the acceleration data acquired by the acceleration sensor. .

  In order to enlarge the detection space for infrared transmission / reception, infrared transmission / reception in a direction in which detection is impossible is stopped or weakened in advance. Thus, unnecessary power consumption can be reduced.

Example of functional configuration diagram of name tag type sensor terminal of the present invention Example of overall system configuration diagram of an embodiment of the present invention Specific example of block configuration of name tag type sensor terminal Specific example of block configuration of base station Example of arrangement of infrared transmitter / receiver in name tag type sensor terminal and example of inclination when wearing Example of wearing and leaving the name tag type sensor terminal Example of infrared transceiver control judgment by acceleration data Example of sensing control judgment based on acceleration data The figure which shows the example formula of the encoding method of the infrared communication signal for meeting detection The figure which shows the example of the encoding system of the infrared communication signal for long distances Example of infrared transceiver control judgment by long-range infrared communication data Example of direction of 3-axis acceleration sensor of name tag type sensor terminal and time change of acceleration y component Example of current consumption reduction effect by the present invention Example of reducing power consumption when passing each other Example of tilt determination using acceleration components in two directions

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 shows an example of the minimum configuration of a terminal that controls unnecessary infrared transmission / reception based on acceleration sensor data in the present invention.

  The name tag type sensor terminal (TR) includes a microprocessor (MPU), a triaxial acceleration sensor (AC), a storage unit (STRG), a battery (BT), and an infrared transceiver (TRIR1, TRIR2, TRIR3, TRIR4). The triaxial acceleration sensor (AC) acquires acceleration data of the name tag type sensor terminal (TR) and transfers the data to the microprocessor (MPU). The microprocessor (MPU) stores acceleration data in the storage unit (STRG). The microprocessor (MPU) can refer not only to the current acceleration data but also to past acceleration data by referring to the acceleration data stored in the storage unit (STRG). From the acceleration data, the movement and inclination of the nameplate type sensor terminal (TR) can be determined.

  When the three-direction component values of x, y, and x in the acceleration data are all constant, it can be determined that the name tag type sensor terminal (TR) is not worn and left. At this time, since the name tag type sensor terminal (TR) performs unnecessary infrared transmission / reception, if it is determined that the name tag type sensor terminal is left unattended based on the acceleration data, the infrared transmission / reception of the name tag type sensor terminal is stopped.

  When the name tag type sensor terminal (TR) is inclined at an angle of φ1 or more with respect to the vertical direction, the infrared transmitter / receiver (IR1) arranged upward at an angle of φ2 from the beginning has a further upward angle φ1 + φ2. . If the angle φ1 + φ2 is equal to or greater than the threshold, the infrared transceiver (TRIR1) does not succeed in transmission / reception. Therefore, when an angle of φ1 or more is detected from the acceleration data, unnecessary power consumption can be avoided by stopping or weakening infrared transmission / reception of the infrared transceiver (TRIR1). The same applies to the infrared transceivers (TRIR2, TRIR3, TRIR4) arranged at different angles other than the infrared transceiver (TRIR1).

  FIG. 2 shows an example of the entire system configuration according to the present invention.

  The name tag type sensor terminal (TR) can be worn by being lowered from the neck, and can acquire the wearer's activity rhythm and face-to-face data. The name tag type sensor terminal (TR) transmits the sensed data from the transceiver unit (TRSR) to the cradle (CL). The cradle (CL) transfers data transmitted from the name tag type sensor terminal (TR) to the base station (GW). It also has a function of transmitting time information transmitted from the base station (GW) to the name tag type sensor terminal (TR). The base station (GW) receives the data transmitted from the cradle by the transceiver unit (GWSR1). The received data is stored in the storage unit (GWME). The base station (GW) transmits the data stored in the storage unit (GWME) to the sensor network server (SS) at a predetermined timing (for example, a time determined once a day). The sensor network server (SS) receives the data transmitted from the base station by the transmission / reception unit (SSSR). The received data is stored in the sensor DB (SDB). The content server (CS) acquires data stored in the sensor DB (SDB) via the network at a predetermined timing (for example, a time determined once a day) by the transmission / reception unit (CSR). In the content server (CS), the content generation unit (CNTG) generates content (CNT) based on the acquired sensor data. The display server (DS) acquires content via the network at a predetermined timing (for example, a time determined once a day) by the transmission / reception unit (DSSR). The display server (DS) is connected to an infrared receiver (RIR), and stores infrared data received by the receiver (GWSR2) in an infrared DB (IRDB). When a predetermined infrared ID is received, the content corresponding to the infrared ID is displayed on the display (DIS). As a result, it is possible to prevent others from seeing their data. Of course, the content display on the display (DIS) may be viewed by, for example, logging in by entering a password without using data from the infrared receiver (RIR).

  As described above, it is possible to provide a system capable of acquiring user activity data and feeding back to the user.

  FIG. 3 shows a configuration of a name tag type sensor terminal (TR) which is an embodiment of the name tag type sensor terminal, and the name tag type sensor terminal (TR) has a plurality of infrared transmission / reception units for detecting a human face-to-face situation. (AB), a triaxial acceleration sensor (AC) for detecting the wearer's movement, a microphone (AD) for detecting the wearer's speech and surrounding sounds, and illuminance for detecting the front and back of the name tag type sensor terminal Various sensors such as sensors (LS1F, LS1B) and temperature sensors (AE) are mounted. The sensor to be mounted is an example, and other sensors may be used to detect the face-to-face condition and movement of the wearer.

  The infrared transmitter / receiver (AB) continues to periodically transmit terminal information (TRMT), which is unique identification information of the name tag type sensor terminal (TR), in the front direction. When a person wearing another name tag type sensor terminal (TR) is positioned substantially in front (for example, front or oblique front), the name tag type sensor terminal (TR) and the other name tag type sensor terminal (TR) Terminal information (TRMT) is exchanged by infrared rays. In this way, it is possible to record who is facing who.

  Name tag type sensor terminals in the organization activity visualization / analysis system are equipped with multiple infrared transmission / reception circuits at different mounting angles in order to improve the performance of face-to-face information acquisition when the person is in a face-to-face position relationship. .

  In general, light has higher straightness than electromagnetic waves of other wavelengths, and it is easy to optically strictly control the communication range with a lens. As a result, it is possible to detect that they are in a face-to-face state, not just in close proximity. Here, infrared light which is invisible to human eyes is used, but of course, visible light or ultraviolet light may be used. In this embodiment, a case where four sets of infrared transceivers (TRIR1 to TRIR4) are mounted is illustrated.

  Each infrared transceiver is generally composed of a combination of an infrared light emitting diode for infrared transmission and an infrared phototransistor. The infrared ID transmission unit (IRID) generates terminal information (TRMT) which is its own ID and transfers it to the infrared light emitting diode of the infrared transmission / reception module. In this embodiment, all the infrared light emitting diodes are turned on simultaneously by transmitting the same data to a plurality of infrared transmission / reception modules. Of course, independent data may be output at different timings.

  In particular, according to the present invention, some or all of the plurality of infrared transmission / reception circuits mounted at different angles are optical axes emitted by the respective light emitting elements, or optical axes of the detection light received by the respective light receiving elements. However, they are arranged so as to be directed inward toward the outside of the housing. In the most typical embodiment, the optical axes cross in front of the housing. Thereby, the dimension of the housing opening for transmitting infrared rays can be reduced, which contributes to miniaturization and robustness of the terminal.

  The data received by the infrared phototransistor of the infrared transmitter / receiver (AB) is logically ORed by an OR circuit (IROR). That is, if the ID is received by at least one of the infrared light receiving units, the name tag type sensor terminal recognizes the ID. Of course, a configuration having a plurality of ID receiving circuits independently may be employed. In this case, since the transmission / reception state can be grasped with respect to each infrared transmission / reception module, it is also possible to obtain additional information, for example, in which direction the other name tag type sensor terminal facing each other is.

  Infrared transceivers (IRTR1 to IRTR4) perform infrared communication with high directivity for detecting face-to-face communication between wearers, whereas the area beacon receiver (ABR) performs infrared communication for a wider range of communication. It is a communication receiver. By detecting the ID of an infrared transmitter (beacon) installed in a conference room or the like, it is detected that the wearer is in that room. Since this infrared communication is performed over a wider range, typically infrared communication modulated at 38 kHz or the like is used.

  The self-diagnosis (SDG) is a circuit for determining a failure of the infrared transmission / reception unit. It has an open / close circuit that individually blocks received data received by a plurality of infrared receiving circuits. A failure of the infrared transmission / reception circuit can be determined by individually checking whether the data transmitted by the terminal's own infrared transmission circuit can be received by the specific infrared reception circuit.

  The sensor data (SENSD) detected by the sensor is stored in the storage unit (STRG) by the sensor data storage control unit (SDCNT). The sensor data (SENSD) is processed into a transmission packet by the communication control unit (TRCC) and transmitted to the base station (GW) by the transmission / reception unit (TRSR).

  Transmission and reception of data are not limited to wireless and wired systems. In some implementations, the acquired data is continuously transmitted wirelessly continuously or intermittently. Alternatively, a cable may be connected to the sensor terminal to acquire the data by wire and transmit it to the base station (GW).

  At this time, it is the communication timing control unit (TRTMG) that generates sensor data (SENSD) from the storage unit (STRG) and generates the transmission timing. The communication timing control unit (TRTMG) has a plurality of time bases (not shown) that generate a plurality of timings.

  In addition to the sensor data (SENSD) currently detected by the sensor, the data stored in the storage unit includes summary gift data (CMBD) accumulated in the past, and firmware for updating the operation program of the name tag type sensor terminal. Firmware update data (FMUD), self-diagnosis failure determination result (DIAG), time information (TRCK), operation setting (TRMA), terminal information (TRMT), and the like.

  The name tag type sensor terminal (TR) of the present embodiment detects that the external power supply (EPOW) is connected by the external power supply connection detection circuit (PDET), and generates an external power supply detection signal (PDETS). The transmission timing generated by the communication timing control unit (TRTMG) is switched by the external power supply detection signal (PDETS), and data to be transmitted to the base station is selected. For example, the current sensor data (SENSD) is not transmitted during charging, and past data that has not been transmitted (CMBD) is collectively transmitted to the base station, firmware update data is received, etc. Switch the operation mode.

  The illuminance sensors (LS1F, LS1B) are mounted on the front surface and the back surface of the name tag type sensor terminal (TR), respectively. Data acquired by the illuminance sensors (LS1F, LS1B) is stored in the storage unit (STRG) by the sensor data storage control unit (SDCNT), and at the same time is compared by turning over detection (FBDET). When the name tag is correctly mounted, the illuminance sensor (front) (LS1F) mounted on the front surface receives external light, and the illuminance sensor (back) (LS1B) mounted on the back surface is the name tag type sensor terminal. Since the positional relationship is sandwiched between the main body and the wearer, no extraneous light is received. At this time, the illuminance detected by the illuminance sensor (front) (LS1F) takes a larger value than the illuminance detected by the illuminance sensor (back) (LS1B). On the other hand, when the name tag type sensor terminal (TR) is turned over, the illuminance sensor (back) (LS1B) receives extraneous light and the illuminance sensor (front) (LS1F) faces the wearer side. ) The illuminance detected by the illuminance sensor (back) (LS1B) is larger than the illuminance detected by (LS1F).

  Here, by comparing the illuminance detected by the illuminance sensor (front) (LS1F) and the illuminance detected by the illuminance sensor (back) (LS1B) by turning over detection (FBDET), the name tag terminal is turned over and correctly It can be detected that it is not attached. When turning over is detected by turning over detection (FBDET), a warning sound is generated from the speaker (SP) to notify the wearer.

  The microphone (AD) acquires audio information. The surrounding information such as “noisy” or “quiet” can be known from the sound information. Furthermore, by analyzing the voice of a person with voice feature analysis (SNA), whether communication is active or stagnant, whether conversations are being exchanged equally, unilaterally speaking, or angry? You can analyze face-to-face communication such as whether you are laughing. Furthermore, the face-to-face state that the infrared transmitter / receiver (AB) cannot detect due to the standing position of a person can be supplemented by voice information and acceleration information. Information analyzed by the speech feature analysis (SNA) is typically frequency analysis such as fast Fourier transform (FFT) or zero crossing of acquired speech, or analysis of energy change.

  The triaxial acceleration sensor (AC) detects the acceleration of the terminal, that is, the movement of the terminal. For this reason, from the acceleration data, it is possible to analyze the intensity of movement of a person wearing the name tag type sensor terminal (TR) and behavior such as walking. Further, by comparing the acceleration values detected by a plurality of name tag type sensor terminals (TR), the activity of communication between the persons wearing the name tag type sensor terminals (TR), mutual rhythm, and mutual correlation Etc. can be analyzed.

  In the name tag type sensor terminal (TR) of this embodiment, the data acquired by the three-axis acceleration sensor (AC) is stored in the storage unit (STRG) by the sensor data storage control unit (SDCNT), and at the same time, the vertical detection is performed. The direction of the name tag is detected by (UDDET). This is based on the fact that the acceleration detected by the three-axis acceleration sensor (AC) is observed as two types of dynamic acceleration changes due to the movement of the wearer and static accelerations due to the gravitational acceleration of the earth. . By using the static acceleration data, it is possible to determine the inclination and orientation of the name tag type sensor terminal (TR).

  When the name tag type sensor terminal (TR) is worn on the chest, the display device (LCDD) displays personal information such as the affiliation and name of the wearer. In other words, it behaves as a name tag. On the other hand, when the wearer holds the name tag type sensor terminal (TR) in his hand and points the display device (LCDD) toward himself, the turn of the name tag type sensor terminal (TR) is reversed. At this time, the contents displayed on the display device (LCDD) and the function of the button are switched by the up / down detection signal (UDDETS) generated by the up / down detection (UDDET). In this embodiment, information to be displayed on the display device (LCDD) according to the value of the up / down detection signal (UDDETS), the analysis result by the infrared activity analysis (ANA) generated by the display control (DISP), and the name tag display (DNM) ).

  Whether or not the name tag type sensor terminal (TR) has faced another name tag type sensor terminal (TR) by exchanging infrared rays between the terminals, that is, the name tag type sensor terminal (TR). It is detected whether or not the person wearing is facing a person wearing another name tag type sensor terminal (TR). For this reason, it is desirable that the name tag type sensor terminal (TR) is mounted on the front part of a person. As described above, the name tag type sensor terminal (TR) further includes a sensor such as a triaxial acceleration sensor (AC). The sensing process in the name tag type sensor terminal (TR) corresponds to the organization dynamics data acquisition (A) in FIG. 2A.

  In many cases, there are a plurality of name tag type sensor terminals (TR), and each of them is connected to a nearby base station (GW) to form a personal area network (PAN).

  The temperature sensor (AE) of the name tag type sensor terminal (TR) indicates the temperature of the place where the name tag type sensor terminal (TR) is located, and the illuminance sensor (table) (LS1F) indicates the illuminance such as the front direction of the name tag type sensor terminal (TR). To get. As a result, the surrounding environment can be recorded. For example, it is possible to know that the name tag type sensor terminal (TR) has moved from one place to another based on temperature and illuminance.

  As input / output devices corresponding to the worn person, buttons 1 to 3 (BTN1 to 3), a display device (LCDD), a speaker (SP) and the like are provided.

  The storage unit (STRG) is specifically composed of a non-volatile storage device such as a hard disk or a flash memory, and includes terminal information (TRMT) that is a unique identification number of the name tag type sensor terminal (TR), sensing interval, and display Operation settings (TRMA) such as output contents are recorded. In addition, the storage unit (STRG) can temporarily record data and is used to record sensed data.

  The communication timing control unit (TRTMG) is a clock that holds time information (GWCSD) and updates the time information (GWCSD) at regular intervals. In order to prevent the time information (GWCSD) from deviating from other name tag type sensor terminals (TR), the time information periodically corrects the time according to the time information (GWCSD) transmitted from the base station (GW).

  The sensor data storage control unit (SDCNT) controls the sensing interval of each sensor according to the operation setting (TRMA) recorded in the storage unit (STRG), and manages the acquired data.

  Time synchronization acquires time information from the base station (GW) and corrects the clock. Time synchronization may be executed immediately after an associate described later, or may be executed in accordance with a time synchronization command transmitted from the base station (GW).

  When transmitting and receiving data, the radio communication control unit (TRCC) controls the transmission interval and converts it into a data format compatible with transmission and reception. If necessary, the wireless communication control unit (TRCC) may have a wired communication function instead of wireless communication. The wireless communication control unit (TRCC) may perform congestion control so that transmission timing does not overlap with other name tag type sensor terminals (TR).

  Associate (TRTA), particularly when this embodiment is implemented by wireless communication, associate request (TRTAQ) for forming a personal area network (PAN) with the base station (GW) shown in FIG. 1B and associate response (TRTAR). ) To determine a base station (GW) to which data is to be transmitted. Associate (TRTA) is when the power of the name tag type sensor terminal (TR) is turned on, and when the name tag type sensor terminal (TR) is moved, the transmission / reception with the base station (GW) is interrupted. To be executed. As a result of the association (TRTA), the name tag type sensor terminal (TR) is associated with one base station (GW) in the near range where the radio signal from the name tag type sensor terminal (TR) reaches.

  The transmission / reception unit (TRSR) performs data transmission and reception with the base station. Wireless communication may be used, and if necessary, the transmission / reception unit (TRSR) can perform transmission / reception using a connector for wired communication. Transmission / reception data (TRSRD) transmitted / received by the transmission / reception unit (TRSR) is transferred to / from the base station (GW) via the personal area network (PAN).

  FIG. 4 mainly shows the internal system configuration of the base station (GW). Communication between the base station and the name tag type sensor terminal may be either wired or wireless. In the case of radio, a plurality of base stations (GWs) are arranged so as to cover areas such as living rooms and workplaces in consideration of radio reach. The base station (GW) includes a transmission / reception unit (GWSR1, 2), a storage unit (GWME), a clock (GWCK), and a control unit (GWCO).

  The transceiver unit (GWSR) receives data from the name tag type sensor terminal (TR) and performs wired or wireless transmission to the base station (GW). At this time, the name tag type sensor terminal (TR) can also receive infrared light emitted from a stationary infrared transmitter (PIR). Further, the transmission / reception unit (GWSR1) includes an antenna for receiving radio waves or a connector for wired connection with a cradle or the like.

  The storage unit (GWME) is configured by a nonvolatile storage device such as a hard disk or a flash memory. The storage unit (GWME) stores at least operation setting (GWMA), data format information (GWMF), terminal management table (GWTT), and base station information (GWMG). The operation setting (GWMA) includes information indicating an operation method of the base station (GW). The data format information (GWMF) includes information indicating a data format for communication and information necessary for tagging the sensing data. The terminal management table (GWTT) includes terminal information (TRMT) of subordinate name tag type sensor terminals (TR) that can be currently associated, and local information distributed to manage the name tag type sensor terminals (TR). Includes ID. The base station information (GWMG) includes information such as the address of the base station (GW) itself. The storage unit (GWME) temporarily stores the updated terminal firmware (GWTF) of the name tag type sensor terminal.

  The storage unit (GWME) may further store a program executed by a central processing unit CPU (not shown) in the control unit (GWCO).

  The clock (GWCK) holds time information. The time information is updated at regular intervals. Specifically, the time information of the clock (GWCK) is corrected by time information acquired from an NTP (NETWORK TIME PROTOCOL) server (TS) at regular intervals.

  The control unit (GWCO) includes a CPU (not shown). When the CPU executes a program stored in the storage unit (GWME), sensing data sensor information acquisition timing, sensing data processing, transmission / reception to the name tag type sensor terminal (TR) and sensor network server (SS) It manages the timing and timing of time synchronization. Specifically, when the CPU executes a program stored in the storage unit (GWME), the communication control unit (GWCC), associate (GWTA), time synchronization management (GWCD), time synchronization (GWCS), etc. Execute the process.

  The communication control unit (GWCC) controls the timing of communication with the name tag type sensor terminal (TR) and the sensor network server (SS) by wireless or wired. Further, the communication control unit (GWCC) distinguishes the type of received data. Specifically, the communication control unit (GWCC) identifies from the header portion of the data whether the received data is general sensing data, data for association, or a time synchronization response. And pass these data to the appropriate functions.

  The communication control unit (GWCC) refers to the data format information (GWMF) recorded in the storage unit (GWME), converts the data into a format suitable for transmission / reception, and indicates the type of data Data format conversion (GWMF) to which tag information is added is executed.

  The associate (GWTA) transmits a response (TRTAR) to the associate request (TRTAQ) sent from the name tag type sensor terminal (TR), and transmits a local ID assigned to the name tag type sensor terminal (TR). If the associate is established, the associate (GWTA) corrects the terminal management information using the terminal management table (GWTT) and the terminal firmware (GWTF).

  Time synchronization management (GWCD) controls the interval and timing for executing time synchronization, and issues a command to synchronize time. Alternatively, the sensor network server (SS), which will be described later, executes time synchronization management (GWCD), so that the command can be sent from the sensor network server (SS) to the base station (GW) of the entire system. .

  Time synchronization (GWCS) connects to an NTP server (TS) on the network, and requests and acquires time information. Time synchronization (GWCS) corrects the clock (GWCK) based on the acquired time information. Time synchronization (GWCS) transmits a time synchronization command and time information (GWCSD) to the name tag type sensor terminal (TR).

  FIG. 5 is an example of the arrangement of the infrared transmitter / receiver in the name tag type sensor terminal and the inclination of the name tag type sensor terminal.

  FIG. 5A is an example of the arrangement of four infrared transceivers. The infrared transmitter / receiver (TRIR1) is arranged facing down to the left, the infrared transmitter / receiver (TRIR2) is oriented upward to the left, the infrared transceiver (TRIR3) is oriented downwards to the right, and the infrared transceiver (TRIR4) is oriented upwards.

  FIG. 5B shows an example where the name tag type sensor terminal is tilted upward. Since the name tag type sensor terminal itself faces upward, the direction in which the infrared transmitter / receiver (TRIR2, 3) arranged at the upward angle transmits / receives infrared rays is further upward. For this reason, in the infrared transmitter / receiver (TRIR2, 3), even if infrared transmission is performed, the other terminals are hardly received, and even in the infrared reception state, infrared light from other terminals can hardly be received. That is, the success rate of infrared transmission / reception approaches zero. By detecting the inclination of the name-tag type sensor terminal from the acceleration data, the infrared transmission / reception (TRIR2, 3) of the infrared transmitter / receiver (TRIR2, 3) is stopped or weakened near zero, and unnecessary power consumption is reduced. At this time, since the infrared transceivers (TRIR1, 4) are oriented in the direction in which infrared transmission / reception is possible, the infrared transmission / reception is not stopped or weakened. Instead of infrared transmission / reception (TRIR2, 3), the infrared transmission / reception unit (TRIR1, 4) transmits infrared transmissions instead of the infrared transmission / reception unit (TRIR2, 3) so that the number of infrared transmissions / receptions is constant throughout the nameplate type sensor terminal. May be.

  FIG. 5C shows an example in which the name tag type sensor terminal is tilted downward. Since the name tag type sensor terminal itself faces downward, the direction in which the infrared transceivers (TRIR1, 4) arranged at the downward angle transmit and receive infrared rays is further downward. For this reason, the success rate of infrared transmission / reception of the infrared transceivers (TRIR1, 4) approaches zero. By detecting the inclination of the name tag type sensor terminal from the acceleration data, the infrared transmission / reception (TRIR1, 4) of the infrared transmitter / receiver (TRIR1, 4) stops or weakens the infrared transmission / reception close to zero, and reduces unnecessary power consumption. At this time, since the infrared transceivers (TRIR2, 3) are oriented in the direction in which infrared transmission / reception is possible, the infrared transmission / reception is not stopped or weakened. Infrared transmitters / receivers (TRIR2, 3) send infrared transmissions instead of infrared transmitters / receivers (TRIR1, 4) so that the number of infrared transmissions / receptions is constant throughout the nameplate type sensor terminal. May be.

  FIG. 6 shows an example in which a name tag type sensor terminal is worn by a person and left on a desk or the like. When a person wears a name tag type sensor terminal (TR1), the name tag type sensor terminal (TR1) detects a change in acceleration, such as expansion and contraction of the body during breathing, even if the person is stationary. Moreover, when it hangs from the neck, the plane part of the name tag type sensor terminal (TR1) faces vertically downward. Since the acceleration sensor can detect the gravitational acceleration, it can be determined from the acceleration data that the name tag type sensor terminal (TR1) is in the direction lowered from the neck.

  On the other hand, there is almost no change in acceleration for the name tag type sensor terminal (TR2) left on the desk or the like. Although a minute change is detected by a slight vibration of the building itself, it can be clearly distinguished from a case where a person wears it in a stationary state. In addition, when left on the desk as shown in FIG. 6, the flat surface of the name tag type sensor terminal (TR2) is parallel to the desk surface. Since the acceleration sensor can detect the gravitational acceleration, it can be determined from the acceleration data that the name tag type sensor terminal (TR2) is left on the desk as shown in FIG.

  That is, it can be determined from the acceleration data whether the name tag type sensor terminal is in a worn state or in a neglected state.

  Usually, the name tag type sensor terminal continues the sensing operation even when it is not worn. However, even if the sensing operation is performed while being left on the desk as shown in FIG. 6, only insignificant data different from the user activity is acquired. Therefore, when such non-wearing data is acquired, it is necessary to remove it from the actual activity data.

  Therefore, if the name tag type sensor terminal itself detects the non-wearing state from the acceleration data and stops the sensing operation such as infrared transmission / reception, the power consumption of the name tag type sensor terminal can be reduced, and the non-wearing state is determined by the host system. -The removal process can be made unnecessary.

  FIG. 7 is a flowchart of control of the infrared transceiver using acceleration data according to the present invention.

  When the name tag type sensor terminal is activated and starts the sensing operation, this flowchart is started (701).

  The name tag type sensor terminal detects acceleration data for a predetermined time (702), and calculates the inclination of the name tag type sensor terminal from the data (703). Since the name tag type sensor terminal is equipped with N infrared transceivers in different directions, each infrared receiver (i) (704) determines whether infrared transmission / reception is possible or not. (705). If the direction is such that infrared transmission / reception is not possible, the infrared transmission / reception of the infrared transmission / reception unit is stopped (706). This determination and control is applied to all N infrared transceivers (707).

  FIG. 8 is a flowchart of sensing operation control using acceleration data in the present invention.

  When the name tag type sensor terminal is activated and starts the sensing operation, this flowchart starts (801).

  The name tag type sensor terminal detects (802) and stores (803) acceleration data for a certain period of time, calculates the change amount of the acceleration data of the name tag type sensor terminal from the data, and determines whether the change amount is equal to or less than a threshold value. Determine (804). If it is below the threshold, the sensing operation is stopped for a predetermined time (805). If the threshold is exceeded, sensing other than acceleration is continued (806). In addition, the sensing operation is stopped, and sensing other than acceleration is continued even after a predetermined time has elapsed (806).

  FIG. 9 shows an embodiment of a short-range infrared communication signal encoding method according to the present invention.

  The data to be transmitted is 2 bytes, and as a means for confirming whether or not the transmission data has been correctly received, a total of 4 bytes of 2 bytes of CRC16 are transmitted.

  The transmission data is encoded for each byte. The start bit of logical value 0 indicating the beginning of the byte is 1 bit and 8 bits of transmission data, and the stop bit of logical value 1 indicating the end of the byte is 1 bit, for a total of 10 bits of data. Encoding in this way facilitates transmission and reception by serial communication.

  Here, the transmission time of 1 bit is 16 μs, and the transmission time of 4 bytes as a whole is 0.14 ms and 0.64 ms. For example, if communication is performed once per second, this time is sufficiently short, and is suitable as the transmission time.

  Infrared light is emitted when the logical value is 0, and is not emitted when the logical value is 1. In order to reduce power consumption during infrared light emission, the light emission pulse may be shorter than 16 μs, which is a transmission time for one bit. For example, it may be about 3 μs.

  Infrared data transmitted / received by TRIR1 to TRIR6 has high directivity and is used to detect facing each other at a relatively short distance, while area detection infrared communication received by an area beacon receiver (ABR). The system has low directivity and can receive even reflected light, and is used to detect data transmitted by an area beacon (AB) described later over a relatively long distance.

  FIG. 10 shows an embodiment of the encoding method of the area detection infrared communication method. The area detection infrared communication system is an infrared communication different from the normal short-range infrared communication for face-to-face detection, and can communicate over a distance of several tens of meters. Thereby, it is possible to detect whether or not the user is present in a certain room. Note that the term “infrared transmission / reception” in this document refers to short-range infrared communication for face-to-face detection, not area detection infrared communication, that is, long-range infrared communication.

  The area beacon (AB) typically has 16 bits for 2 bytes of its own identification information, and 2 bytes for which the logical value of the data information is inverted as a means of confirming whether the transmission data has been received correctly. 16 bits are transmitted. Before transmitting the entire data, a logical value 1 is transmitted for 1 ms and a logical value 0 is transmitted for 1 ms as a leader code indicating the head of the data. The transmission data is encoded bit by bit, and when the data information is 0, the logical value 1 is transmitted for 500 μs and the logical value 0 is transmitted for 500 μs. When the data information is 1, a logical value 1 is transmitted for 500 μs and a logical value 0 is transmitted for 1500 μs. Finally, a logical value 1 is transmitted for 500 μs as a stop bit indicating the end of the data.

  Although the transmission time differs depending on whether the data information is 0 or 1, the total transmission time becomes a fixed 50 ms by adding information obtained by inverting the logical value of the data information. For example, if communication is performed once every 10 seconds, this time is sufficiently short, and is suitable as the transmission time.

  Infrared light is emitted when the logical value is 1, and is not emitted when the logical value is 0. In order to further increase the transmission distance and reduce the power consumption during infrared light emission, the light emission of logical value 1 is modulated into short pulses. FIG. 10 (F) shows an example in which the pulse is modulated to a pulse of 40 kHz duty 50%, for example. Of course, a modulation frequency other than 40 kHz may be used.

  FIG. 11 is a flowchart of face-to-face infrared transmission / reception control using long-range infrared communication data in the present invention.

  If the name tag type sensor terminal is activated and starts the sensing operation, this flowchart starts (1101).

  The name tag type sensor terminal detects (1102) and stores (1103) long-distance communication infrared identification data for a certain period of time, and the number of detections of long-distance communication infrared identification data within a certain period of time from the data It is determined whether or not there is (1104). If it is less than or equal to the threshold value, face-to-face infrared transmission and reception is stopped for a predetermined time (1105). If the threshold value is exceeded, the face-to-face infrared transmission / reception is continued (1106). Further, the face-to-face infrared transmission / reception is stopped, and the face-to-face infrared transmission / reception is continued even after a predetermined time elapses (1106).

  Long-distance communication infrared communication can detect the presence of a room. For this reason, it is detected by long-distance communication infrared identification data that there is no possibility for other people to enter or a room where it is meaningless to detect face-to-face data, and face-to-face infrared transmission / reception for the time in the room is detected. Stop and reduce power consumption.

  FIG. 12 is an example of a time change graph of data acquired in the three-axis directions of x, y, and z and the acceleration y component in the name tag type sensor terminal (TR). As shown in FIG. 12, in the name tag type sensor terminal (TR), the vertical direction is the y-axis direction in the normal wearing state. Therefore, the inclination of the name tag type sensor terminal (TR) can be estimated from the acceleration y component data.

  Let λ be the value of the acceleration y component when the upward infrared transmitter / receiver (IRTR) mounted on the name tag type sensor terminal (TR) has an inclination that makes infrared transmission / reception unsuccessful. In the time zone in which the value of the acceleration y component exceeds λ in the time change of the acceleration y component, infrared transmission / reception of the upward infrared transmitter / receiver (IRTR) mounted on the name tag type sensor terminal (TR) is not successful. Therefore, unnecessary power consumption can be reduced by stopping or weakening infrared transmission / reception of the infrared transmitter / receiver (IRTR) in a time zone in which the value of the acceleration y component exceeds λ.

  FIG. 13 shows an example of current consumption that can be reduced by the present invention. Conventionally, the total operation of the name tag type sensor terminal (TR) is about 6 mA, of which infrared transmission is 1 mA and infrared reception is 0.5 mA. When the battery capacity is 200 Ahr, the operation time is 30 hours.

  When the infrared ray stop ratio is 1/4, the current consumption is 0.75 mA for infrared transmission and 0.375 mA for infrared reception. At this time, the operating time is 32 hours. When the infrared ray stop ratio is 1/2, the current consumption is 0.5 mA for infrared transmission and 0.25 mA for infrared reception. At this time, the operating time is 34.3 hours. That is, according to the present invention, if the infrared transmission / reception for 1/4 of the operation time is stopped, the operation time is increased by 2 hours, and if the infrared transmission / reception for 1/2 the operation time is stopped, the operation time is increased by 4.3 hours. It becomes possible to do.

  FIG. 14 shows a method for controlling infrared transmission / reception when passing each other.

  Passing occurs when one or both of the two are walking. Also, in passing each other, the two are not completely in front, but pass left and right. For this reason, in the six infrared transceivers (TRIR1, 2, 3, 4, 5, 6), the receiver facing the other party has more detections than the other receivers, and the other party As a result, the distance at which infrared rays transmitted from the partner name tag type sensor terminal (TR2) can be detected becomes longer. Regarding the number of detections, for example, a difference as shown in the table of FIG. 14 occurs.

  In FIG. 14, when the name tag type sensor terminal (TR1) of the user A is passing by the user B, the TRIRs 3, 4 and 6 of the infrared transceivers face the user B side. Therefore, when approaching the user B, the infrared transceivers TRIR3, 4, 6 can detect infrared rays earlier than other infrared transceivers.

  If it is determined from the value of the acceleration sensor that the user A is in a walking rhythm and only one of the infrared transmitters / receivers TRIR3, 4 and 6 receives infrared rays, the other user will be on his right side. It can be estimated that they are located and passing each other. In this case, since the infrared transceivers TRIR1, 2 and 5 are in a direction in which it is difficult to detect the passing, unnecessary power consumption is reduced by weakening the infrared transmission / reception of the infrared transceivers TRIR1, 2 and 5 during the passing of both. Can be reduced.

  FIG. 15 shows a method of using the z and y component values of the triaxial acceleration component for the inclination in the name tag type sensor terminal.

  As shown in FIG. 15A, the name tag type sensor terminal has a shape approximating a rectangular parallelepiped. Therefore, the acceleration applied to the name tag type sensor terminal in the stationary state is only the gravitational acceleration. Therefore, in this case, only the inclination of the name tag type sensor terminal is reflected in the value of the acceleration sensor. The x, y, and z directions are three axes of the right hand system. If the y direction of the name tag type sensor terminal is determined, the corresponding z direction can also be uniquely determined. That is, since the y component value and the z component value are subordinate to each other, the z component value can be obtained from the y component value.

  However, when a name tag type sensor terminal is worn, the rhythm of the person's body is reflected, so that vibrations and tilt changes always occur. That is, the values of the three components of the acceleration sensor are not simply a tilt, but are also influenced by the acceleration applied to the name tag type sensor terminal. For this reason, the values of the y component and the z component are not completely subordinate to each other. For example, when the name tag type sensor terminal moves in the z direction, the z component of acceleration changes more than the y component. For this reason, when acceleration is frequently applied to the name tag type sensor terminal, as shown in FIG. 15B, it may not be possible to obtain an inclination determination accuracy suitable for stopping infrared transmission / reception only with the acceleration value of the y component.

  Therefore, the inclination of the name tag type sensor terminal is determined using the values of both the y component and the z component. In FIG. 15B, even if the value of the acceleration y component is equal to or greater than the threshold value λy, the name tag type sensor terminal in FIG. The machine (TRIR2, 3) is not in the direction where infrared transmission / reception is not possible. Therefore, when the value of the acceleration y component is equal to or greater than the threshold value λy and the value of the acceleration z component is equal to or less than the threshold value λz, if the infrared transceiver (TRIR2, 3) stops infrared transmission / reception, the two-way infrared transmission / reception that was originally detectable is possible. Will not be detected until.

  Therefore, whether to stop the transmission / reception of the infrared transceivers (TRIR2, 3) is determined when the acceleration y component is equal to or greater than the threshold λy and the value of the acceleration z component is equal to or greater than the threshold λz. By providing this determination condition, the inclination detection accuracy is improved when only the value of one component of acceleration is used when the name tag type sensor terminal is moving.

  Similarly, for the infrared transceivers (TRIR1, 4) in FIG. 15D, the inclination of the infrared transmission / reception is determined using the values of both the y component and the z component with high accuracy. In that case, the infrared transmission / reception is stopped.

  As described above, it is possible to detect an infrared transmitter / receiver in a direction in which infrared transmission / reception is actually impossible with high accuracy, stop the infrared transmission / reception, and reduce unnecessary power consumption. When the determination is made based only on the y component value, the misjudgment rate is about 40%, but the misjudgment rate can be suppressed to about 10% by making a determination including the value of the z component. That is, it has been clarified that there is an effect of suppressing erroneous determination.

Claims (10)

  Equipped with a plurality of infrared transceivers and acceleration sensors, the infrared transceivers transmit and receive infrared data to and from other terminals and transmitters to detect that they are facing each other or close to each other, and the acceleration sensors detect movement and tilt. A sensor terminal for detecting, wherein a part or all of a plurality of infrared transceivers are controlled based on the acceleration data acquired by the acceleration sensor.   The sensor terminal according to claim 1, wherein the plurality of infrared transceivers are arranged in different directions.   2. The sensor terminal according to claim 1, wherein the control of the plurality of infrared transmitters / receivers is any one or all of stop of infrared transmission / reception, weakening of the amount of infrared emission, reduction of the number of infrared emission, and increase of the infrared transmission interval. A sensor terminal comprising:   The sensor terminal according to claim 1, wherein from the acceleration data detected by the acceleration sensor, it is determined whether or not the sensor terminal is worn by a person, and when it is determined that the sensor terminal is not worn. A sensor terminal, which stops infrared transmission / reception.   5. The sensor terminal according to claim 4, wherein infrared transmission / reception is started when it is detected from the acceleration data detected by the acceleration sensor that the sensor terminal is worn by a person. Terminal.   The position between the said sensor terminal and other sensor terminals at the time of meeting in the sensor terminal of Claim 2 from the arrangement | positioning position of the said infrared transmitter / receiver among the several said infrared transmitter / receivers, and the frequency | count of having received infrared rays. A sensor terminal characterized by estimating a relationship.   The sensor terminal according to claim 6, wherein the positional relationship between the sensor terminals and the movement of the sensor terminal at the time of meeting are estimated from the acceleration data detected by the acceleration sensor of the sensor terminal. .   It is equipped with a short-range infrared transceiver and a long-range infrared transceiver, detects a facing state by short-range infrared communication by the short-range infrared transceiver, and in a fixed space by long-range infrared communication by the long-range infrared transceiver. A sensor terminal for detecting a presence state, wherein the infrared transmission / reception of the short-range infrared transceiver is controlled when specific long-range infrared data is detected a predetermined number of times or more within a predetermined time. Sensor terminal.   The sensor terminal according to claim 8, wherein the control of the plurality of infrared transmitters / receivers is any one of stopping infrared transmission / reception, weakening the amount of infrared emission, decreasing the number of infrared emission, increasing the infrared transmission interval, or Sensor terminal characterized by including all.   Equipped with a plurality of infrared transmitters / receivers and acceleration sensors, the infrared transmitters / receivers transmit / receive infrared data to / from other sensor terminals and transmitters to detect that they are facing each other or close to each other, and the acceleration sensors detect movements and inclinations. A plurality of infrared transmitters / receivers arranged in different directions, detecting whether infrared rays are received by any of the infrared transmitters / receivers, and detecting a walking state by the acceleration sensor; A sensor terminal characterized in that, by determining, the passing of only a short time closer than a predetermined time is extracted, and the direction of each sensor terminal at the time of the passing is estimated.

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