JPH04101597A - Radio telemeter system - Google Patents

Abstract

PURPOSE:To reduce power consumption and to permit operation for an extended period of time by transmitting the change in a sensor immediately after it is detected and letting a self-diagnosis report on a line test be made by the actuation of an information transmitter side at an appropriate time interval. CONSTITUTION:When a sensor detects the occurrence of abnormal information, an information transmitter 1 simultaneously transmits the information by radio. To execute self-diagnosis of a line at a specified time interval, a timer value of a self-diagnosing signal transmission timer is set and transmitted from a monitoring part 8 through an information receiver 5 to the information transmitter 1. The information transmitter 1 confirms and sets the received timer value and goes into a condition of power suspension. In cases where no abnormal information occurs in the sensor of the information transmitter 1 for an extended period of time, the transmitter-receiver of the information transmitter 1 is actuated when the timer value set in the information transmitter 1 has completely been counted up. Then the self-diagnosing signal for confirmation of the abnormality of the line is transmitted to execute transmission with an information receiver 5, and when no abnormality is found the information transmitter 1 goes into the condition of power suspension again.

Description

DETAILED DESCRIPTION OF THE INVENTION (Technical field to which the invention pertains) The present invention relates to a wireless telemeter system that unmannedly observes the situation in a remote location, transmits the observation data via radio waves, and remotely monitors the system at a manned monitoring station.

(Prior art and its problems) In security monitoring equipment, etc., in devices or places where it is difficult to transmit change information of sensors installed in a distant monitoring area by wire for remote monitoring, it is generally difficult to transmit that information by wire. Remote monitoring is carried out using radio waves to transmit information. In this case, whether or not batteries are often used as the operating power source for local information transmitters, it is possible to avoid maintenance and inspection work such as battery replacement over a long period of time, and to detect changes in information immediately. It is required that the information be communicated reliably.

Conventionally, the following methods have been used for this purpose.

■ A remote control method in which only the receiving section of the information transmitter installed in the monitoring area is operated, and the transmitter of the information transmitter is operated to send information in response to an information transmission request from the monitoring side.

■ A method in which the information transmitter installed at the site is always inactive, and the information transmitter is equipped with a timer and activated at predetermined times to send out information.

■ A method in which the information transmitter installed at the site is always inactive, and is activated and transmits information only when a change occurs in the sensor output.

In this way, the operating time of the information transmitter is shortened, battery power consumption is reduced, and long-term operation is achieved.

However, the above-mentioned method (2) lacks immediacy in transmitting abnormality information, and has the disadvantage that the receiving section constantly consumes operating power. In the method (3) above, as in (2) above, there is a drawback that the transmission of abnormality information lacks immediacy, and there is no change in the sensor output. In addition, in the method (①) above, if the information transmitter side breaks down, the monitoring side will either be unable to send out information because there is no change in the sensor, or the information transmitter may be out of order. A major drawback is that it is unclear whether information will be received or not.

(Objective of the Invention) The present invention solves the above-mentioned drawbacks, provides instantaneous sensor operation, has a self-diagnosis function for line and equipment failures, and has a wireless communication system that reduces battery consumption on the information transmitter side. Its purpose is to provide a telemetry system.

(Structure and operation of the invention) The wireless meter system of the present invention has the immediacy of transmitting the information immediately when a change in the sensor is detected, and has the ability to transmit the information immediately when a change in the sensor is detected, and is capable of transmitting the information immediately between the information transmitter side (monitored side) and the information receiver side. side (monitoring side)
The monitoring side is responsible for time management of self-diagnosis reports for line tests including communication equipment, and self-diagnosis reports are made when the information transmitter side is activated.
It is characterized by lengthening or shortening it depending on the situation, such as at night, to lengthen the effective downtime of the information transmitter, suppressing battery consumption, and allowing operation for a long period of time without requiring battery replacement or maintenance. shall be.

That is, in the wireless telemeter system of the present invention, an information transmitter placed in a monitoring area detects and wirelessly transmits various states of the monitoring area, and the radio waves from the information transmitter are transmitted to an information receiver installed in a remote location. In a wireless telemeter system that performs remote monitoring by receiving information on a device, the information transmitter includes a detection unit that detects various states of a monitoring area, and a system that transmits detection information obtained by the detection unit from the detection unit. A wireless transmitter/receiver that transmits wirelessly upon request and receives return data from the information receiver; a battery power source that supplies power to each section; and a battery power source that turns on and off the supply of operating power to the wireless transmitter/receiver. When a power saving circuit and a specified time set based on a transmission request from the detection section or a specification from the information receiver are reached, the power saving circuit is turned on to supply the battery power to the radio transmitting/receiving section. When time data indicating the specified time added to the return data from the information receiver is received, the power saving circuit is turned off to stop supplying power to the wireless transmitter/receiver section. and a control unit, wherein the information receiver, when receiving a wireless signal from the information transmitter, sends the information transmitter a time indicating the specified time determined to reduce power consumption of the battery power source. The present invention is characterized in that it includes a control section that performs control to add data to return data and send it out.

The structure and operation of the present invention will be explained below with reference to the drawings.

FIG. 1 is a block diagram showing an example of the overall configuration of a wireless telemeter system according to the present invention. In the figure, ■ is an information transmitter equipped with a sensor that is installed in a distant monitoring area, and transmits the information wirelessly at the same time as abnormality information is generated from the sensor.

Reference numeral 5 denotes an information receiver installed on the monitoring side, and upon receiving information from the information transmitter 1, it sends the received information back to the information transmitter 1. The information transmitter 1 receives the reception report from the information receiver 5, and sends a confirmation signal to the information receiver 5 when it confirms that it matches the transmitted information. Only when the information receiver 5 receives the confirmation signal from the information transmitter 1 does it output the information from the information transmitter 1 to the monitoring section 8 and notify the supervisor by displaying it or sounding an alarm. In this way, the monitor can detect reliable abnormality information at the site.

On the other hand, in order to perform line self-diagnosis at predetermined time intervals, a timer value of a self-diagnosis signal sending timer is set and sent from the monitoring section 8 to the information transmitter l via the information receiver 5. The information transmitter 1 checks and sets the received timer value, and enters a power-off state (sleeve mode). If abnormal information is not generated in the sensor of information transmitter 1 for a long time, the transmitter/receiver of information transmitter 1 will start when the timer value set in information transmitter 1 times up, and an abnormality will be detected in the line. It sends out a self-diagnosis signal to check whether there is a malfunction or not and communicates with the information receiver 5, and if there is no abnormality, it operates to enter the sleeve mode again.

FIG. 2 is a block diagram showing details of a configuration example of the information transmitter 1 shown in FIG. 1. In the figure, reference numeral 11 denotes a wireless transmitting/receiving section, which wirelessly transmits detection information and receives return data from the information receiver 5. Since the wireless transmitter/receiver 11 consumes a large amount of power, the voltage V is supplied from the battery 20 via the power saving circuit 19. The power supply link circuit 19 is connected to the control unit (MPU) 18 so as to be supplied with the power of D2.
It is controlled to start and go to rest by a control signal from the wireless transmitter/receiver 11, and is normally in a resting state (sleeve mode), with the power to the wireless transmitter/receiver 11 being off.

Reference numeral 13 denotes a detection unit that detects a change in the state of a sensor, and when a change (abnormality) occurs in one or more sensors, it detects the number of the sensor that caused the change and the situation of the change.

Reference numeral 14 denotes an interrupt activation command unit that issues an interrupt activation command to the control unit 18 to put the information transmitter 1 into an operating state when the detection unit 13 detects a change in the sensor.

15 is a programmable timer counter, which counts the time until the timer value specified by the information receiver 5 on the monitoring side is given priority or the timer value specified in advance in the ID-ROM 17 is reached when no specification is given from the information receiver 5. However, in any case, there is a timer counter which gives a start command to the control section 18 when the time has elapsed, and is constructed of a CMO3-IC and is always in operation with low power consumption.

17 is an ID-ROM composed of EEP-ROM
The identification number unique to the information transmitter and the detection unit 13
This is a memory unit that stores unique numbers given to each sensor and the operation sequence of the information transmitter. Normally, it is a sleeve motor, and is activated by an instruction from the control unit 18 as necessary.

18 is a control unit (
processor section). Usually located in sleeve mote,
It wakes up in response to a start command from the interrupt start command unit 14 or the programmable timer counter 15 and performs control operations.

19 is an operating power source V o D 2 which is supplied from the battery 20 to the wireless transmitting/receiving unit 11 which consumes a large amount of power under the control of the control unit 18 .
A power saving circuit (Power
Saver).

Reference numeral 20 denotes a battery that serves as an operating power source for the information transmitter 1, and a lithium secondary battery, a solar battery, a nickel cadmium alkaline secondary battery, or the like is used.

Next, FIG. 3 is a block diagram showing a detailed configuration example of the information receiver 5 of FIG. 1. The information receiver 5 installed on the monitoring side is always in a receiving operation state in order to receive radio waves sent from the information transmitter 1. In the figure, 51 is a wireless transmitter/receiver for performing wireless communication with the wireless transmitter/receiver 11 of the information transmitter 1. Reference numeral 53 denotes an ID-ROM configured as an EEP-ROM, and is a memory section that stores an identification number unique to the information receiver, an operation sequence of the information receiver, and the like. 54 is a control unit (microprocessor) that controls the entire device.

55 is an input/output unit (I
lo).

5G has a power supply unit that supplies operating power for the entire device, including a voltage stabilization unit (Reg) 561 and an uninterruptible power supply unit 56.
2 and a commercial power supply section (Rec, ) 563.

Next, the operation of the present invention will be explained with reference to the flowcharts shown in FIGS. 4 and 5.

FIG. 4 is a flowchart showing the operation of the information transmitter 1, and 101 to 120 indicate step numbers.

Normally, the detection section 13, programmable timer counter 15, and time timer 1G of the information transmitter 1 always operate with extremely small power consumption, and the wireless transmitting/receiving section 11 is in a sleeve state.

When the abnormal signal from the sensor is detected by the detection unit 13 (1
01) or when the self-diagnosis time t1 set in the programmable timer counter 15 times up (102
) All the circuits including the power saving circuit I9 are powered on and become operational (103).

For example, when a sensor such as a smoke detector, a temperature detector, or a waste detector detects an abnormality, the detection unit 13 is activated, and a start signal is sent from the interrupt start command unit 14 to the control unit 18 and sent to the sleeve motor. The control unit 18 enters the operating state, gives an operating power supply command to the power saving circuit 19, and the operating power is supplied to the wireless transmitting/receiving unit 11, which consumes a large amount of power, and the power is turned on.
state (103).

Step 104 is a process of setting the number of verifications N and the number of retransmissions M when communicating with the information receiver 5 in steps 113 to 119. In step 105, the number of the sensor that detected the abnormality and the abnormality information are stored in the ID-ROM 17.
The detected information is encoded by comparing it with the contents of the data, and prepared as transmission data. In addition, when communication cannot be established even after retransmitting M times after checking N times in steps 113 to 115, the sending code memory (
Step 120) is searched and prepared as transmission data.

Next, in step 106, communication is performed with the information receiver 5 via the control channel, a wireless air channel is searched, and a wireless channel for transmitting and receiving data with the information receiver 5 is selected. The transmission data prepared in step 105 is transmitted using the selected wireless channel. Step 108 and step 10
4, data is transmitted and received a set number of times (N times), and the transmitted code is compared with the returned data from the information receiver 5 to determine whether or not they match.

Then, it is determined in step 109 whether or not there is a designation of self-diagnosis time t1 from the information receiver 5 at the same time as the returned data, and if there is an instruction to set the timer value t1, the value t is set in the programmable timer counter 15. At the same time, the power is turned off and the wireless transmitting/receiving section 11 of the information transmitter 1 is set to sleep mode (step 112). The above operations return to the initial normal state.

In this way, the information transmitter 1 becomes operational only when there is a transmission request when the sensor is abnormal, or when the self-diagnosis time t1 is set in the programmable timer counter 15. Moreover, the self-diagnosis time t1 is Since the information receiver 5, that is, the monitoring unit 8, can change the self-diagnosis time depending on security needs during the day and at night, it is possible to effectively set the information transmitter 1 in sleeve mode to reduce battery power consumption. It can be reduced to the minimum necessary.

Step 120 is performed when a code match cannot be obtained in step 108 due to the execution of steps 113 to 119, for example, due to poor radio wave condition of the wireless line.
This is a storage process in which the transmission data prepared in step 5 and the time of the timer 16 are stored in the memory and retransmitted at the next transmission. That is, in order to ensure the transmission information on the wireless line, data is transmitted N times (three times in this example) for code verification, and when there is a discrepancy as a result of the N number of code verification transmissions, the verification transmission is stopped and a predetermined transmission is performed. time interval h (e.g. t2=20 seconds)
If communication is not established even after retrying M times (three times in this example) to retransmit the data, the data is stored.

The self-diagnosis timer value (tl) is changed from the monitoring unit 8 to 1 as necessary.
It is possible to arbitrarily set the time at which the next self-diagnosis transmission is requested during the data communication of 07.

Next, the operation of the information receiver 5 will be explained.

FIG. 5 is a flowchart showing the operation of the information receiver 5. In the figure, 501 to 510 are step numbers. The information receiver 5 is always in a reception standby state, and starts operating depending on whether or not there is reception from the information transmitter 1 via the control channel (step 501). When a wireless channel for data communication is selected, it is then determined whether data is being received (step 502). If the data reception is not successful, the data reception is canceled after a predetermined time t3 and returns to the initial state. When receiving data, the received data is returned to confirm the received contents, and at the same time, a self-diagnosis time (tl) is sent to the information transmitter 1 as necessary. Communication is carried out N times, the number of transmission and reception verifications set in the information transmitter 1, and the transmission data and reception data are verified against each other, and when they match, the communication is terminated (steps 503 to 504).

The presence or absence of self-diagnosis data is determined in step 505, and the communication data is transmitted to the monitoring section 8 in steps 506 and 507. If the communication data in step 503 specifies a self-diagnosis time (tl) for the information transmitter 1, the setting of the self-diagnosis timer value (tl) is changed in steps 508 and 509, and the system restarts and stands by. returns to state. If the self-diagnosis signal is not received from the information transmitter 1 even after the time set in step 509 has elapsed, it is determined that a failure has occurred in the communication system of the information transmitter 1, and a failure report is transmitted to the monitoring unit 8. .

If there is no abnormality in the sensor and the control channel has not been received for a long time, in step 511, the time (t+') including the timer error is calculated from the previously specified self-diagnosis time (tl).
Thereafter, it is determined that some kind of failure has occurred in the line or the communication system of the information transmitter 1, and a failure report is transmitted to the monitoring unit 8 in step 512.

An embodiment of the monitoring wireless telemeter system according to the present invention has been described above.

In this embodiment, the case of information transmitter 1 and information receiver 5, or 1 to 1, has been explained, but it is also possible to monitor multiple information transmitters with one information receiver, and in that case, 4
This can be realized by setting a difference in the retransmission timer value t2 shown in the example of the figure for each information transmitter to eliminate overlap in wireless communication time.

(Effects of the Invention) As explained in detail above, by implementing the present invention in a security monitoring device, etc., when a condition monitoring sensor installed in a remote location detects an abnormality, the monitoring side can be immediately notified. The information is transmitted immediately, and the power consumption of the battery of the information transmitter for abnormality reporting can be reduced to the necessary minimum, so maintenance intervals such as battery replacement can be lengthened. Furthermore, failure diagnosis of the line equipment can be automatically carried out at a specified time from the monitoring side, which has an extremely large effect on improving the reliability of abnormality information data.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an overall configuration example of a wireless telemeter of the present invention, FIG. 2 is a detailed configuration example diagram of an information transmitter of the present invention, and FIG. 3 is a detailed configuration example diagram of an information receiver of the present invention. FIG. 4 is an operational flowchart of the information transmitter side of the present invention, and FIG. 5 is an operational flowchart of the information receiver side of the present invention. ■...Information transmitter, 5...Information receiver, 8...Monitoring section, 11...Wireless transmission/reception section, 13...Detection section, 14
... Interrupt start instruction section, 15... Programmable timer counter, 16... Time timer (clock section), 17
... ■D-ROM, 18... Control section (processor section), 19... Power save circuit, 20... Battery, 5
1... Wireless transmitting/receiving unit, 53... ID-ROM, 54
. . . control section (processor section), 55 . . . l10 (input/output section), 56 . . . power supply section. Figure 4 of the Puppet map

Claims (1)

[Claims] An information transmitter placed in a monitoring area detects and wirelessly transmits various states of the monitoring area, and radio waves from the information transmitter are received by an information receiver installed in a remote location. In a wireless telemeter system that remotely monitors by a wireless transmitting/receiving unit that transmits data and receives return data from the information receiver; a battery power supply that supplies power to each unit; and a power saving circuit that turns on and off the supply of operating power from the battery power supply to the wireless transmitting and receiving unit. , when a specified time set by a transmission request from the detection unit or a specification from the information receiver is reached, the power saving circuit is turned on to supply the battery power to the wireless transmitting/receiving unit, and the information receiver a control unit that performs control to turn off the power saving circuit and stop supplying power to the wireless transmitting/receiving unit when receiving time data indicating the specified time added to the return data from , when the information receiver receives a wireless signal from the information transmitter, the information receiver sends time data indicating the specified time determined to reduce power consumption of the battery power source to the information transmitter as return data. A wireless telemeter system characterized by comprising a control unit that performs control to add and send data.