JP2011055383A - Information communication method - Google Patents

Abstract

The present invention provides an information communication method for reducing power consumption required for communication operations in both a master station and a slave station in a synchronous communication system that performs communication in a time division multiplex system.
An information communication method in a synchronous communication system in which a plurality of mobile stations become one master station and a plurality of slave stations, and share a communication channel in a time division multiplexing system, and the input state of the switch of the slave station The length of the sleep time of the communication established synchronously between the master station and the slave station is changed according to the first time, the length of the sleep time is determined by the importance of the event generated by the input of the switch It is determined based on the third index 93 obtained by combining the index 90 and the second index 91 determined by the elapsed time from the event generated by the input of the switch.
[Selection] Figure 7

Description

  The present invention relates to low power consumption in a synchronous communication system.

  The control for reducing the power consumption in the conventional synchronous communication system is performed as follows. First, a master station forming a time division multiplexing time slot transmits a beacon serving as a reference for the time slot to a plurality of slave stations. Then, the slave station that detected the beacon makes a connection request from the slave station to the master station based on the network control information included in the beacon, and notifies the time slot to be assigned to the slave station if the master station can connect. To do. Since the communication from the slave station to the master station is performed only in the assigned time slot, low power consumption is realized by entering the sleep state at times other than the time slot.

  When the slave station detects the pause period of the transmission data, the slave station transmits transmission pause time reference information to the master station. The master station obtains a transmission time interval based on the transmission pause reference information, and from the master station to the slave station. The power consumption can also be reduced by a method of transmitting and transmitting the slave station according to the transmission time interval (see, for example, Patent Document 1).

  As another method, the slave station determines the second period from the predetermined first period information when the slave station is in the power saving mode and notifies the master station. The master station is in the power saving mode. By allocating the period at the time, the power consumption in the slave station is reduced (see, for example, Patent Document 2).

JP-T-2002-517940 JP 2008-187289 A

  However, in the conventional configuration, the master station that performs the synchronous communication system manages time slots for time division multiplexing and transmits beacons that always form time slots in response to requests from an unspecified number of slave stations. Since it is necessary to perform an operation and a reception operation to wait for communication from the slave station, there is a problem that the effect of reducing the power consumption in the synchronous communication method cannot be obtained.

  Therefore, an object of the present invention is to realize a reduction in power consumption in communication operation between a master station and a slave station when the master station and a plurality of slave stations communicate in a synchronous communication system.

  In order to achieve this object, the information communication method of the present invention provides information communication in a synchronous communication system in which a plurality of mobile stations become one master station and a plurality of slave stations, and share a communication channel in a time division multiplexing system. The method is characterized in that the length of the sleep time of communication established synchronously between the master station and the slave station is changed according to the input state of the switch of the slave station.

  According to the information communication method of the present invention, an appropriate sleep time is set in the master station and each slave station from the operation state of the master station and the slave station, and power consumption required for communication operation in both the master station and the slave station Can be reduced.

The figure which shows the application image in embodiment of this invention Top view of information terminal Top view of thermometer Diagram showing measurement flow Diagram showing communication procedure of synchronous communication method Diagram showing the slot configuration of the master station Diagram showing sleep interval determination sequence Diagram showing slot interval control time chart

  Embodiments of the information communication method of the present invention will be described below in detail with reference to the drawings.

(Embodiment)
FIG. 1 is an application image to which an information communication method according to an embodiment of the present invention is applied, and is a simple inspection system used in a hospital or the like. A wireless network 4 serving as a communication channel between the information terminal 1 of the nurse 3 serving as the parent station among the mobile stations and the simple testing device 2 individually used by a plurality of patients 5 serving as child stations among the mobile stations. Is formed. In this wireless network 4, the information terminal 1 of the nurse 3 operates as a master station, and the simple examination device 2 of the patient 5 operates as a slave station. The information terminal 1 collects the results of each patient 5 measured by the simple inspection device 2 including patient information.

  In the present embodiment, the simple inspection device 2 is described as a thermometer having a network function, but the present invention can be applied to other inspection devices.

  FIG. 2 shows a top view of the information terminal 1. The information terminal 1 is a PDA (Personal Digital Assistant), and the system is turned on by turning on the power switch 20. The display panel 11 includes a menu display unit 13 and a status display unit 14. The menu display unit 13 displays an operation menu that can be currently selected for operation. The status display unit 14 displays the results of operation and communication.

  The switch group 12 includes a confirmation key 15, an up cursor key 16, a down cursor key 17, a left cursor key 18, and a right cursor key 19, and the up cursor key 16 and the down cursor key 17 are displayed on the menu display unit 14. The cursor displayed on the display panel 11 is operated using the left cursor key 18 and the right cursor key 19, and the operation is determined by the enter key 15.

  FIG. 3 shows a top view of the thermometer. As the present embodiment, the simple inspection device 2 is a thermometer that measures the body temperature by bringing the body temperature measuring unit 26 into contact with the human body. However, the simple test apparatus 2 can be applied to any test apparatus such as a sphygmomanometer, a heart rate monitor, a weight scale, or a blood glucose meter that is operated by the patient 5 and measures biological information.

  The thermometer power switch 23 is a switch for turning the thermometer power ON / OFF. The measurement mode switch 24 switches whether the thermometer is set to a body temperature measurement mode or a mode for referring to past measurement data stored in the thermometer. When set to the body temperature measurement mode, the thermometer prepares for body temperature measurement and performs communication processing with the information terminal 1. If the reference mode is selected, each time the communication switch 25 is turned on, the past measurement data is displayed in a new order in time. Communication of measurement data is not performed in the reference mode. The communication switch 25 transmits the measured data by communication. The display panel 22 displays status information indicating the measured value, measurement state, communication state, remaining battery level, and the like.

  FIG. 4 shows the measurement flow. The measurement flow shows how the communication unit included in each device operates by the display and operation of each device on the information terminal 1 operated by the nurse 3 and the thermometer operated by the patient 5. .

  When the thermometer is operated 30 to turn on the power switch by the operation of the patient 5, the communication unit is initialized and set up in the reception mode. During the setup period, the communication unit searches for an information terminal that can communicate with the surrounding situation, and if it finds the information terminal 1 that is a communicable master station device, it performs slot synchronization so that synchronous communication is possible.

  Similarly, the information terminal 1 is activated by the operation 31 of the power switch ON by the operation of the nurse 3, and the communication unit automatically initializes and performs setup. The setup waits for a slot allocation request for synchronous communication from a thermometer as a peripheral slave station device, and if there is a slot allocation request, allocates an appropriate slot. Thereafter, the device search mode is entered in order to respond to the connection request from the thermometer.

  The nurse 3 selects the data collection mode from the menu displayed on the display panel 11 by operating the cursor, and presses the confirmation key 15 so that the information terminal 1 receives the connection request for communication. Preparation for displaying the device ID of the thermometer that transmits the request is completed.

  On the patient 5 side, the measurement mode switch of the thermometer is turned on, and temperature measurement with the thermometer is started. At this time, the communication unit of the thermometer transmits a connection request command 32. In addition to the command, a device ID, which is a unique ID of the thermometer, and a patient ID indicating the patient 5 are simultaneously transmitted to the connection request command.

  When the information terminal 1 accepts the connection request command, the information terminal 1 displays the patient ID of the device that transmitted the connection request on the status display unit 14 of the information terminal. The nurse 3 confirms the device ID and the patient ID, and selects the patient ID if there is no mistake in the patient 5 to be measured from here. When the patient ID is selected, the communication unit transmits a connection permission command 33 to the thermometer that has transmitted the connection request command. In the connection permission command, the device ID of the information terminal 1 and the device ID of the thermometer permitted to connect are transmitted together.

  When the thermometer responds to the connection permission command with its own device ID, the thermometer stores the device ID of the information terminal 1, and thereafter uses the device ID of the information terminal 1 as a destination address. The thermometer transmits a communication establishment request 34 with the device ID of the information terminal 1 as the destination address and the own device ID as the transmission address, and the information terminal transmits a communication establishment response 35 in response to the communication establishment request. The display mode 11 displays that the establishment of communication has been established, and enters the reception mode in order to receive measurement data from the thermometer.

  When the thermometer receives a communication establishment response, it displays on the display panel 22 that communication has been established. In these connection request procedures, the nurse 3 can confirm the grasp of the patient 5 and the grasp of the device by exchanging the device ID and the patient ID with each other. This has the effect of preventing access from authorized terminals.

  The patient 5 loads a thermometer and measures the body temperature. When the measurement is completed, the patient 5 sounds an alarm notifying the completion of the measurement and displays the measured body temperature value on the display panel 22. When the patient 5 confirms his / her body temperature and performs a transmission switch ON operation 36 to transmit the body temperature data, the body temperature data is transmitted 37 from the communication unit. In addition to the body temperature data, the patient ID is sent together with the body temperature data.

  When receiving the body temperature data, the information terminal 1 displays the received body temperature data together with a message indicating the completion of measurement on the display panel 11. After the nurse 3 confirms the patient ID sent together with the device ID and body temperature data as the transmission address, and confirms that the device ID and patient ID stored in the connection procedure are correct, it is stored together with the body temperature data. The When the confirmation of the body temperature data is completed, a data reception response is transmitted 38 from the communication unit of the information terminal 1.

  When the thermometer receives the data reception response, it displays transmission completion on the display panel 22.

  When the patient 5 has completed all body temperature measurements, the communication switch 25 is turned ON again, and a disconnection request command is transmitted 39 in the communication unit.

  When receiving the disconnection request command, the information terminal 1 displays the patient ID and the disconnection request message on the display panel 11. When the nurse 3 can accept the disconnection request, when a menu indicating disconnection is selected, a disconnection command is transmitted 40 from the communication unit.

  When the thermometer receives a disconnection command addressed to its own station, it transmits a disconnection completion command 41 and displays a message on the display panel 22 indicating that communication has been disconnected.

  When receiving the disconnection completion command, the information terminal 1 displays a message on the display panel 11 indicating that communication with the patient ID has been disconnected.

  While the nurse 3 and the patient 5 operate the device in the measurement flow, the communication unit maintains the reception state, but shifts to the low power consumption mode to the extent that the communication quality is maintained. The information terminal 1 and the thermometer communicate with each other using the synchronous communication method. In the synchronous communication method, the time slot to be transmitted / received by the own station is determined. Therefore, in the time slot section other than the own station, the power of the communication unit is controlled and consumed. Reduce power.

  FIG. 5 shows a communication procedure of the synchronous communication method. The synchronous communication method is a method in which a plurality of communication terminals share a communication channel by time division multiplexing. In order to establish communication by time division multiplexing, there are a master station that controls time synchronization and a slave station that operates according to the control of the master station. In this embodiment, the master station is the information terminal 50, and the slave stations are the simple inspection devices A51, B52, and C53.

  The information terminal 50 defines a slot cycle 54 as a logical communication channel, and equally divides it to form a slot 55. The slot 55 is a control slot 56 (denoted as C), a first slot 57 (denoted as 1), a second slot 58 (denoted as 2), a third slot 59 (denoted as 3), and a fourth slot 60 (denoted as 4). ) Is set.

  By transmitting the beacon 61, the information terminal 50 causes the simple inspection device A51, the simple inspection device B52, and the simple inspection device C53 to detect the time position of the slot cycle 54.

  When the power supply is turned on (62), the simple inspection apparatus A51 performs a receiving operation. When the beacon 61 is detected, a slot allocation request 63 is transmitted to the information terminal 50 during the control slot 56. When the information terminal 50 receives the slot allocation request 63, the information terminal 50 selects a currently available slot. Since the first slot 57 can be used, the first slot permission 64 in the first slot 57 is transmitted to the simple inspection device A51. Thereafter, the simple inspection terminal A51 performs transmission / reception using the section of the first slot.

  When the simple inspection terminal B52 is turned on (65), the reception operation is continued until the first beacon transmitted by the information terminal 50 is received. The time from when the power is turned on until the first beacon is detected is measured as a beacon waiting time 66. Similarly, the simple inspection apparatus C53 is powered on (67), continues the reception state until the first beacon is received, and measures the beacon waiting time 68 until the beacon is detected.

  If the first beacon 69 is detected after the simple inspection apparatus B52 and the simple inspection apparatus C53 are turned on, the slot allocation requests 70 and 71 are transmitted to the information terminal 50. The simple inspection apparatus B52 requests the slot allocation request. 70 can be transmitted, but the simple inspection device C53 waits for a connection request 72 and does not transmit the slot allocation request 71.

  Since only the control slot 56 is used before various communication terminals form a synchronous communication procedure with the information terminal 50, transmission timing may collide. Therefore, in order to avoid this collision, the terminal transmitting in the control slot 56 has a back-off time. This back-off time is the time from when a beacon is received until the slot allocation request is transmitted, and is inversely proportional to the beacon waiting time. The shorter the beacon waiting time, the longer the back-off time.

  Therefore, the slot allocation request 70 of the simple inspection apparatus B52 having a long beacon waiting time is transmitted first. The simple inspection device C53 having a short beacon waiting time when the beacon 69 is transmitted tries to transmit the slot allocation request 71 after the back-off time has elapsed, but the simple allocation device B52 first transmits the slot allocation request 70. Therefore, the connection request wait 72 is entered, and the slot allocation request 71 is not transmitted. Then, the simple inspection device C53 that has become the connection request wait 71 transmits a slot allocation request in the next slot cycle.

  When the information terminal 50 receives the slot allocation request 70 from the simple inspection device B52, since it performs transmission / reception 73 with the simple inspection device A51 in the first slot, the second slot permission 74 is assigned to the simple inspection device B52 in the second slot. Send to. Thereafter, the simple inspection apparatus B52 performs transmission / reception using the section of the second slot.

  When the information terminal 50 transmits the beacon 75 in the next slot cycle, the simple inspection device C53 transmits a slot allocation request 76. When receiving the slot allocation request 76, the information terminal 50 performs transmission / reception 77 with the simple inspection device A51 in the first slot, and performs transmission / reception 78 with the simple inspection device B52 in the second slot. The slot permission 79 is transmitted to the simple inspection device C53. Thereafter, the simple inspection device C53 performs transmission / reception using the section of the third slot.

  FIG. 6 shows the slot configuration of the master station. The slot 80 is defined as a time width of 2 msec, and each slot is defined as a slot cycle 86 including the control slot 81, the first slot 82, the second slot 83, the third slot 84, and the fourth slot 85 together. ing. Therefore, the slot cycle time is 10 msec.

  Each slot has a transmission slot (denoted as T) and a reception slot (denoted as R), and each slot uses 1 msec, which is 1/2 of the slot. In the control slot 81 and the first slot 82 to the fourth slot 85, the slot positions of the transmission slot and the reception slot are different. That is, in the control slot 81, the transmission slot 87a is the front and the reception slot 87b is the rear. In the first to fourth slots 82 to 85, the reception slot 88b is the front and the transmission slot 88a is the rear. This is because, in the control slot 81, the priority order of the transmission right is the master station device, and in the first to fourth slots 82 to 85 assigned to each slave station, the priority order of the transmission right is in each slave station.

  In the transmission slot 87a of the control slot 81, the information terminal 1 having the master station function broadcasts a beacon 89. The beacon 89 includes a network identification signal and a signal indicating a network connection state. Each station that receives the beacon 89 recognizes a slot using the beacon as a time base point, and receives control information in the network. Therefore, in the slave station, the slot for receiving the beacon 89 is a reception slot. The reception slot 87b is a reception slot to which the slave station that has received the beacon 89 responds. When a slave station makes a response such as a connection request, it responds in this reception slot 87b. However, when a plurality of slave stations access simultaneously, the slave station that started transmission can obtain the transmission right. Therefore, the slave station needs to perform carrier detection in the section of the reception slot 87b. The carrier detection time interval is determined as a value obtained from the back-off time. As a result, a slave station with a short back-off time obtains a transmission right.

  The master station always transmits a beacon 89 to the transmission slot 87 a of the control slot 81. If a slave station not connected to the network makes a connection request, the reception slot 87b of the control slot 81 is used to transmit the ID of the local station necessary for establishing communication together with a slot assignment request command. Upon receiving the slot assignment request command, the master station assigns an unused slot and sends the ID of the slave station and a slot assignment permission command to the transmission slot of the slot in the same slot cycle. When the slave station that sent the slot allocation request receives the slot allocation permission command, it can use the slot as its own slot.

  FIG. 7 shows a sleep interval determination sequence. The thermometer quantifies the operation rank 90 (first index) that defines the importance of the switch to be operated depending on the state of the measurement procedure in the measurement procedure. Further, the operation response rank 91 (second index) indicating that the possibility that the switch is pushed increases with the elapsed time since the switch is operated is quantified. Based on the operation rank 90 and the operation response rank 91, a rank 92 (third index) is calculated. The higher the rank 92, the shorter the sleep time. The operation state 93 indicates the state of the body temperature measurement procedure by operation and communication of the thermometer. A communication command 94 indicates a communication procedure related to the operation state 93.

  When the power is turned on, the operation rank 90 and the operation response rank 91 each indicate “1”. The rank 92 indicates “2” by adding the operation rank 90 and the operation response rank 91. When the measurement mode switch 24 is turned on, the operation response rank 91 increases with time. As a result, rank 92 also increases. This is because, as the time elapses after the measurement mode switch 24 is turned on, the operation of the information terminal is advanced, and there is a high possibility that commands related to communication connection will increase, so it is necessary to shorten the sleep time. .

  When the communication establishment reception 95 of the communication command 94 occurs, it indicates that the communication establishment has been established, and according to the operation procedure of the thermometer, the probability that the data communication is required immediately becomes low, so the value of the operation reaction rank 91 is 1. Return to. However, since the measurement procedure is entered, the value of the operation rank is increased by one rank to “2”, and the rank 92 indicates “3”. The value of the operation response rank 91 once returns to “1”, but since the measurement procedure of the thermometer is advanced, the operation response rank 91 increases with time. Then, when there is a notification 96 of the completion of the measurement of the body temperature, the values of the operation response rank 91 and the operation rank 90 are both “5”. This is because there is a high possibility that the measurement data is transmitted to the information terminal 1 after the measurement is completed. Therefore, the sleep period is minimized so that the communication speed assigned to the thermometer by the information terminal 1 can be maximized.

  When the thermometer transmits data according to the data transmission procedure and then receives a data reception response 97 indicating the completion of the data transmission operation from the information terminal 1, the value of the operation response rank 91 is low because the possibility of data to be transmitted / received is low. Becomes as low as “1”. Since the procedure after the data transmission / reception procedure is a disconnection procedure, the value of the operation rank 90 is set to “3” based on the operation importance of the disconnection procedure.

  In the thermometer, when the communication switch 25 is turned on again, the procedure proceeds to the disconnection procedure 98. When this event occurs, the operation response rank 91 increases with time, and when the communication with the information terminal is disconnected by the disconnection completion reception 99, the operation response rank 91 returns to the initial value “1”.

  Table 1 is a table showing the relationship between the slot interval and the sleep time. The rank 92 determined by the measurement procedure decreases as the value of the slot interval increases. The slot interval is a slot cycle interval in which sleep is continued. That is, the sleep time is adjusted in units of slot cycles.

  FIG. 8 is a slot interval control time chart. The information terminal 100 controls the network as a master station. The master station transmits a beacon 102 to inform other stations of the start of the slot cycle and information about the network. The slot cycle 103 is divided into slots indicated by a slot 104 and used. The slot 104 includes a control slot 105 (denoted as C), a first slot 106 (denoted as 1), a second slot 107 (denoted as 2), a third slot 108 (denoted as 3), and a fourth slot 109 (denoted as 4). ). The thermometer 101 is a slave station, and a slot that can be used by network control of the master station is assigned to the first slot 106.

  In the first slot 106 of the N0th slot cycle 110, the thermometer transfers 111 the numerical value 5 of rank 92 defined above. The information terminal 100 that has received the rank “5” recognizes that the thermometer provides a sleep time of six slots with reference to Table 1, and the first slot 106 used by the thermometer during the slot cycle of N0 + 1 to N0 + 6. Sleeps during the period. In this embodiment, since there is no slave station device other than the thermometer, all the information terminals 100 can be used during the sleep time.

  The thermometer confirms that the rank value 5 has been received and enters the 6-slot sleep period 112. During this 6-slot section 60 msec, no communication operation with the thermometer is performed, so that the power consumed by the communication unit can be reduced.

  The thermometer recovers communication in the slot cycle 113 of the (N0 + 7) th, and when the rank “6” is transferred 114 according to the measurement state of the thermometer, it sleeps again for 50 msec of the 5-slot sleep period 115.

  As described above, since the measurement procedure can be standardized in a simple examination apparatus such as a thermometer, the operation rank indicating the rank of the communication speed required for the operation in the measurement procedure according to the operation of the patient, and the operation By defining an operation response rank that indicates the passage of time since it was performed, the two numerical results are sent as ranks to the master station device, and by setting the sleep period specified by the rank, communication operation is performed. Such power consumption can be reduced.

  The information communication method according to the present invention has an effect of recommending the power consumption for communication by optimizing the sleep time according to the operation state during the operation procedure, and the method for reducing the power consumption in the synchronous communication system of the wireless communication Useful for.

DESCRIPTION OF SYMBOLS 1, 50, 100 Information terminal 2 Simple test apparatus 3 Nurse 4 Wireless network 5 Patient 11 Display panel 12 Switch group 13 Menu display part 14 Status display part 15 Confirmation key 16 Up cursor key 17 Down cursor key 18 Left cursor key 19 Right Cursor key 20 Power switch 21, 101 Thermometer 22 Display panel 23 Power switch 24 Measurement mode switch 25 Communication switch 26 Body temperature measurement unit 30, 31 Power switch ON
32 Connection request command transmission 33 Connection permission command transmission 34 Communication establishment request transmission 35 Communication establishment response transmission 36 Communication switch ON
37 Body temperature data transmission 38 Data receipt response transmission 39 Disconnection request command transmission 40 Disconnection command transmission 41 Disconnection completion command transmission 51 Simple inspection device A
52 Simple inspection device B
53 Simple inspection device C
54, 86, 103 Slot cycle 55, 80, 104 Slot 56, 81, 105 Control slot 57, 82, 106 First slot 58, 83, 107 Second slot 59, 84, 108 Third slot 60, 85, 109 First 4 slots 61, 69, 75, 89, 102 Beacon 62, 65, 67 Power ON
63, 70, 71, 76 Slot allocation request 64 First slot permission 66, 68 Beacon waiting time 72 Connection request waiting 73, 77, 78 Transmission / reception 74 Second slot permission 79 Third slot permission 87a, 88a Transmission slot 87b, 88b Reception Slot 90 Operation rank 91 Operation response rank 92 Rank 93 Operation status 94 Communication command 95 Communication establishment reception 96 Measurement completion notification 97 Data reception response 98 Disconnection procedure 99 Disconnection completion reception 101 Thermometer 110 N0th slot cycle 111, 114 rank numerical value transfer 112 6-slot sleep period 113 N0 + 7 slot cycle 115 5-slot sleep period

Claims (8)

An information communication method in a synchronous communication system in which a plurality of mobile stations become one master station and a plurality of slave stations, and a communication channel is shared by a time division multiplexing method.
An information communication method characterized by changing a length of a sleep time of communication established synchronously between the master station and the slave station according to an input state of a switch of the slave station. The length of the sleep time is
A third index obtained by combining the first index determined by the importance of the event generated by the switch input and the second index determined by the elapsed time from the event generated by the switch input. The information communication method according to claim 1, wherein the information communication method is determined based on an index. The first and second indicators are
Increased as the likelihood of communication between the parent and slave stations increases due to the importance of the event or the time elapsed since the event,
The information communication method according to claim 2, wherein the information communication method decreases after the communication is executed. The information communication method according to any one of claims 1 to 3, wherein the length of the sleep time is changed based on a time division slot interval of the time division multiplexing method. 2. The information communication method according to claim 1, wherein in the time division multiplexing method, a master station transmits communication control information and a beacon serving as a reference for a time division slot, and a slave station performs a transmission / reception operation in synchronization with the beacon. The said time division multiplexing system is comprised from the control slot which transmits / receives a control signal on the basis of the beacon which the said master station transmits, and the several communication slot used exclusively for communication of each sub_station | mobile_unit. Information communication method. The information communication method according to claim 5 or 6, wherein when the mobile station starts communication, carrier detection is performed for an arbitrary time after receiving the beacon, and transmission is performed if carrier detection is not performed during the period. 8. The time from when a slave station is activated to when a beacon is first detected is measured, and an arbitrary time for performing carrier detection is changed based on the time until the beacon is detected. Information communication method.

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