JP2014068097A - Communication terminal device and operation control method of the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a communication terminal device and its operation control method that can reduce power consumption other than the time of communication with a sensor device while securing versatility of interface means with the sensor device.SOLUTION: A communication terminal device comprises: interface means for receiving data transmitted by a sensor device at a prescribed cycle Ts; and control means for performing control to transfer the data received by the interface means to an external device via a communication line. The control means is configured to set a data acceptance period with prescribed time length to receive data at every cycle of integral multiple of Ts, to receive the data by starting the interface means after start of the data acceptance period, and to stop the interface means after completion of the data acceptance period.

Description

  The present invention relates to a communication terminal device that transfers data of a sensor device to an external device (for example, a remote center server device) via a communication line, and an operation control method thereof.

  The remote monitoring system (telemetry system) collects meter reading values such as gas, water, and electricity measured by sensor devices and meteorological data such as temperature, humidity, air volume, and atmospheric pressure with a communication terminal device. This is a system that transfers data from the device to the center server device for processing, and is widely introduced as one of the applications of M2M communication.

  Here, in order to connect a wide variety of sensor devices to a general purpose, the communication terminal device and the sensor device are connected via a general serial interface (for example, RS232C) (Non-Patent Document 1).

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  When the communication terminal device and the sensor device are connected via a general serial interface, power consumption in the communication terminal device is a problem. That is, in a communication terminal device connected to a sensor device via a cable, a current on the order of several millimeters to several tens of milliamperes always flows and is consumed even during non-communication. Even if the sensor device and communication terminal device are designed for low power consumption, using a general-purpose interface to connect them increases the total current consumption, making it difficult to drive the battery and places where power supply is constrained Application of was difficult.

  On the other hand, a method of using a signal line provided separately from the serial interface between the sensor device and the communication terminal device and performing wake-up control with a hardware interrupt is also conceivable. However, a unique signal line is required between the sensor device and the communication terminal device, and it is necessary to negotiate in advance the arrangement and control method of the signal line. And versatility will be reduced.

  It is an object of the present invention to provide a communication terminal device and an operation control method thereof that can reduce power consumption when not communicating with the sensor device while ensuring versatility of the interface means with the sensor device.

  According to a first aspect of the present invention, there is provided interface means for receiving data transmitted from the sensor device at a predetermined cycle Ts, and control means for performing control for transferring data received by the interface means to an external device via a communication line. In the communication terminal apparatus, the control means sets a data reception period having a predetermined time length for receiving data every cycle that is an integral multiple of Ts, and activates the interface means after the start of the data reception period. The configuration is such that control is performed to receive the data and stop the interface means after the end of the data reception period.

  In the communication terminal apparatus of the first invention, the control means sets the sleep state after stopping the interface means, and wakes up before starting the interface means.

  In the communication terminal device of the first invention, the control means sets the first data reception period having a time length exceeding Ts as the data reception period, receives the first data, and receives the first data. A second data reception period having a predetermined time length for receiving the second and subsequent data is set for each period that is an integral multiple of Ts from the reception of the second and subsequent data, and the interface unit is activated / Control the stop. Further, the control means sets the start timing of the second data reception period to a predetermined time before the timing that is an integer multiple of Ts from the reception timing of the previous data.

  In the communication terminal device according to the first aspect of the present invention, the control means performs control to terminate the data reception period and stop the interface means after receiving and transferring data during the data reception period.

  In the communication terminal device according to the first aspect of the invention, the control means performs control to stop the interface means after completion of data reception when data reception is started during the data reception period, and sleeps after transfer of the data. Set to state.

  According to a second aspect of the present invention, there is provided a communication terminal for receiving data transmitted from a sensor device at a predetermined cycle Ts by an interface unit and performing control for transferring data received by the interface unit to an external device via a communication line by a control unit In the operation control method of the apparatus, the control means sets a data reception period having a predetermined time length for receiving data every cycle which is an integral multiple of Ts, and activates the interface means after the start of the data reception period. Data is received, and control is performed to stop the interface means after the end of the data reception period.

  In the operation control method for the communication terminal device according to the second aspect of the invention, the control means sets the sleep state after stopping the interface means, and wakes up before starting the interface means.

  The communication terminal device according to the present invention performs a control to autonomously stop the interface unit during a period in which data from the sensor device is not received while using a general-purpose interface unit that receives data from the sensor device. Current consumption can be reduced to the order of microamperes, and the battery driving period can be greatly extended. Thereby, even when it is difficult to secure a power source, it is possible to install a battery-driven sensor device and a communication terminal device.

It is a figure which shows the structure of Example 1 of the communication terminal device of this invention. It is a figure which shows the communication sequence between the communication terminal device 10 in Example 1, and the sensor apparatus 20. FIG. 3 is a flowchart illustrating a processing procedure of a control unit 13 of the communication terminal device 10 according to the first embodiment. It is a figure which shows the communication sequence between the communication terminal device 10 and the sensor apparatus 20 in Example 2. FIG. It is a figure which shows the communication sequence between the communication terminal device 10 and the sensor apparatus 20 in Example 3. FIG. It is a figure which shows the communication sequence between the communication terminal device 10 in Example 4, and the sensor apparatus 20. FIG. It is a figure which shows the structure of Example 5 of the communication terminal device of this invention. It is a figure which shows the structure of Example 6 of the communication terminal device of this invention.

FIG. 1 shows a configuration of Embodiment 1 of a communication terminal apparatus according to the present invention.
In FIG. 1, the communication terminal device 10 includes a power supply unit 11, a communication module 12, a control unit 13, a driver 14, and a connector 15, and power is supplied from the power supply unit 11 to the communication module 12, the control unit 13, and the driver 14. . The sensor device 20 is connected to interface means including the driver 14 and the connector 15 of the communication terminal device 10. Here, the driver 14 and the connector 15 have a configuration corresponding to a serial interface such as RS232C (D-sub 9-pin), USB, RS485, and the like, and have a function of starting / shutdown by a control signal of the control unit 13.

  The communication module 12 connects to the center server device via a wireless or wired communication line (not shown). The control unit 13 performs data transmission / reception control between the driver 14 and the communication module 12 and performs start / shutdown control of the driver 14 by a control signal. Data transmitted from the sensor device 20 is converted into a signal voltage and logic by the driver 14 and input to the control unit 13, and is uploaded from the communication module 12 to the center server device side via the communication line. The sensor device 20 of this embodiment is configured to transmit data at a constant cycle Ts.

  FIG. 2 shows a communication sequence between the communication terminal device 10 and the sensor device 20 in the first embodiment. FIG. 3 illustrates a processing procedure of the control unit 13 of the communication terminal device 10 according to the first embodiment.

  The operation of the first embodiment in which data is transferred from the sensor device 20 to the center server device via the communication terminal device 10 will be described below with reference to FIGS.

  The control unit 13 of the communication terminal device 10 is in a sleep state in a standby state, and the driver 14 is in a shutdown state. When the communication terminal device 10 receives the data reception request transmitted from the center server device, the control unit 13 wakes up by an electrical trigger from the communication module 12. The wake-up control unit 13 activates the driver 14 with a control signal, sets a first data reception period Ta1 for receiving data transmitted from the sensor device 20, and starts data reception. Here, by setting Ta1> Ts, it is possible to receive data (data 1 in FIG. 2) transmitted from the sensor device 20 in the period Ts during the first data reception period Ta1.

  When the control unit 13 receives the data 1 transmitted from the sensor device 20 through the driver 14 during the first data reception period Ta1, the control unit 13 activates the data reception cycle Tp timer from the reception start timing as a starting point. The transmitted data 1 is transmitted to the center server device via the communication module 12. Further, the control unit 13 shuts down the driver 14 after the end of the first data reception period Ta1, and shifts itself to the sleep state. Then, the control unit 13 wakes up in accordance with the end of the data reception cycle Tp timer, and enters a process for receiving the next data 2. In FIG. 2, the shutdown period of the driver 14 and the sleep period of the control unit 13 in the communication terminal device 10 are indicated by hatching.

  Here, when Tp = Ts, the timing for receiving the next data 2 is reached when the data reception cycle Tp timer is completed. However, the next data 2 is received before or after the end of the data reception period Tp timer according to the deviation between the clock mounted on the sensor device 20 and the clock mounted on the communication terminal device 10. Therefore, the control unit 13 wakes up before the data reception cycle Tp timer ends, further activates the driver 14, and sets a second data reception period Ta2 for receiving data 2 from the sensor device 20, Start accepting data. The start timing of the second data reception period Ta2 is, for example, before Ta2 / 2 when the data reception cycle Tp timer ends.

  When the control unit 13 receives the data 2 transmitted from the sensor device 20 through the driver 14 during the second data reception period Ta2, the control unit 13 starts the data reception cycle Tp timer from the reception start timing as a starting point. The transmitted data 2 is transmitted to the center server device via the communication module 12. Furthermore, the control unit 13 shuts down the driver 14 after the end of the second data reception period Ta2, and shifts itself to the sleep state. Thereafter, an intermittent operation is performed in which a second data reception period Ta2 is provided in the data reception cycle Tp, and data after data 2 is sequentially received from the sensor device 20 and uploaded to the center server device.

  The values of Ta1, Ta2, and Tp and the data reception start timing after data 2 are set as appropriate, but may be set directly to the communication terminal device 10 or transmitted from the center server device. A configuration in which the data reception request is superimposed on the remote setting may be employed.

FIG. 4 shows a communication sequence between the communication terminal device 10 and the sensor device 20 in the second embodiment.
In the first embodiment, the data transmission cycle Ts of the sensor device 20 and the data reception cycle Tp of the communication terminal apparatus 10 are the same, but the data reception cycle Tp of the second embodiment is an integral multiple of the data transmission cycle Ts. In FIG. 4, by setting Tp = 5Ts and Ta2 = Ts, the data 1, 6, 11,... Of the sensor device 20 are intermittently received by the communication terminal device 10 and uploaded to the center server device.

  In the second embodiment, the data transmitted from the sensor device 20 is thinned out and uploaded to the center server device. However, even if the data is thinned out, the data is not affected. As a result, the communication frequency can be reduced, so that the compatibility with a narrow-band communication terminal device or a communication terminal device with a limited number of communication due to the battery capacity is good.

FIG. 5 illustrates a communication sequence between the communication terminal device 10 and the sensor device 20 according to the third embodiment.
The control unit 13 according to the first and second embodiments wakes up at the start of the data reception periods Ta1 and Ta2, starts the driver 14, shuts down the driver 14 after the data reception periods Ta1 and Ta2, and sleeps by itself. Had moved to.

  As shown in FIG. 5, the control unit 13 according to the third embodiment aborts the data reception periods Ta1 and Ta2 after completing the transmission of the data received from the sensor device 20 to the center server device, shuts down the driver 14, and goes into the sleep state by itself. It is characterized by migrating. In FIG. 5, the state in which the driver 14 shuts down and the control unit 13 sleeps after data transmission without waiting for the end of the data reception periods Ta1 and Ta2 is shown by hatching the arrows indicating the data reception periods Ta1 and Ta2. As a result, the data reception periods Ta1 and Ta2 can be effectively shortened, and the startup time of the control unit 13 and the driver 14 can be shortened to obtain a high power saving effect.

FIG. 6 illustrates a communication sequence between the communication terminal device 10 and the sensor device 20 according to the fourth embodiment.
The control unit 13 according to the first to third embodiments assumes that data is received from the sensor device 20 and transmitted to the center server device before the end of the data reception periods Ta1 and Ta2.

  In the fourth embodiment, as shown in FIG. 6, it is assumed that data reception starts from the sensor device 20 during the data reception periods Ta1 and Ta2, but the data reception periods Ta1 and Ta2 end before the data reception ends. . In this case, when the driver 14 is shut down at the end of the data reception periods Ta1 and Ta2 and the control unit 13 shifts to the sleep state, data reception and data transmission cannot be performed.

  When the data reception is not completed at the end of the data reception periods Ta1 and Ta2, the control unit 13 according to the fourth embodiment shuts down the driver 14 after the data reception is completed. Further, the control unit 13 shifts to the sleep state after the data transmission to the center server device is completed. That is, if the data reception start timing overlaps with the data reception periods Ta1 and Ta2, data reception can be continued, so that the data reception periods Ta1 and Ta2 can be shortened. Therefore, the activation time of the control unit 13 and the driver 14 can be shortened, and a high power saving effect can be obtained.

FIG. 7 shows the configuration of a fifth embodiment of the communication terminal apparatus according to the present invention.
In FIG. 7, the communication terminal apparatus 10 of the present embodiment has the same configuration as that of the first embodiment, but the power supply to the driver 14 is turned on / off by the semiconductor switch 16 that can be controlled by the control unit 13. In this configuration, the driver 14 having no shutdown function can be used. Further, by providing the semiconductor switch 16 on the GND side, the driver on the sensor device 20 side can be made unloaded, so that the power consumption on the sensor device 20 side can be reduced.

FIG. 8 shows the configuration of Embodiment 6 of the communication terminal apparatus of the present invention.
In FIG. 8, the communication terminal device 10 of the present embodiment has a configuration in which the communication module 12 in the first embodiment is externally attached. That is, the control unit 13 and the communication module 12 are connected via the communication IF (interface) unit 17 and the connector 18. Thereby, it becomes the structure of the communication module 12-communication terminal device 10-sensor apparatus 20, and a flexible response | compatibility also becomes possible also to the change of a communication line.

DESCRIPTION OF SYMBOLS 10 Communication terminal device 11 Power supply part 12 Communication module 13 Control part 14 Driver 15 Connector 16 Semiconductor switch 17 Communication IF part 18 Connector 20 Sensor apparatus

Claims (8)

In a communication terminal device comprising: interface means for receiving data transmitted at a predetermined cycle Ts from a sensor device; and control means for controlling transfer of data received by the interface means to an external device via a communication line ,
The control means sets a data reception period having a predetermined time length for receiving the data every cycle which is an integral multiple of Ts, and activates the interface means after the start of the data reception period to The communication terminal device is configured to perform control to stop the interface unit after the data reception period ends. The communication terminal device according to claim 1,
The communication terminal device is characterized in that the control means sets the sleep state after stopping the interface means and wakes up before starting the interface means. The communication terminal device according to claim 1,
The control means receives the first data by setting a first data reception period having a time length exceeding Ts as the data reception period, and receives the first data and the second and subsequent data. A second data reception period having a predetermined time length for receiving the second and subsequent data is set for each period that is an integral multiple of Ts from the reception, and the start / stop of the interface means is controlled. A communication terminal device. The communication terminal device according to claim 3.
The control means sets the start timing of the second data reception period to a predetermined time before a timing that is an integer multiple of Ts from the reception timing of the previous data. The communication terminal device according to claim 1,
The said control means performs control which stops the said interface means by ending the said data reception period, after receiving and transferring the said data during the said data reception period. The communication terminal device according to claim 1,
The control means performs control to stop the interface means after completion of reception of the data when reception of the data is started during the data reception period, and sets the sleep state after transfer of the data. A characteristic communication terminal device. An operation control method for a communication terminal apparatus, wherein the interface means receives data transmitted from the sensor device at a predetermined cycle Ts, and the control means controls to transfer the data received by the interface means to an external device via a communication line. In
The control means sets a data reception period having a predetermined time length for receiving the data every cycle which is an integral multiple of Ts, and activates the interface means after the start of the data reception period to And controlling the interface unit to stop after the end of the data reception period. In the operation control method of the communication terminal device according to claim 7,
The operation control method for a communication terminal apparatus, wherein the control means sets the sleep state after stopping the interface means and wakes up before starting the interface means.

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