JPH0716274B2 - Wireless telemeter system - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a wireless telemeter system that unattendedly observes a situation in a remote place, transmits the observation data by radio waves, and remotely monitors a manned monitoring station.

(Prior art and its problems) In a security monitoring device or the like, in a device or place where it is difficult to transmit change information of a sensor installed in a distant monitoring area by wire for remote monitoring, that information is generally used. Remote monitoring is carried out using radio waves to communicate the. In this case, a battery is often used as the operating power source for the local information transmitter, but the change in information can be immediately confirmed without performing maintenance work such as battery replacement for as long as possible. Required to be communicated to.

Therefore, the following method has been conventionally implemented.

A remote control method in which only the receiver on the information transmitter side installed in the monitoring area is operated, and the transmitter on the information transmitter side is operated by the information transmission request from the monitoring side to send information.

The information transmitter installed in the field is always stopped,
A system that has a time timer and activates an information transmitter at predetermined times to send information.

The information transmitter installed in the field is always stopped,
A system that activates and sends the information only when the sensor output changes.

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

However, the above-mentioned method has a drawback that the abnormality information is not immediately transmitted and the receiving unit always consumes operating power. In the above method, similar to the above, there is a shortcoming of immediacy in the transmission of abnormal information, and a drawback is that battery power is consumed to operate the information transmitter at a predetermined time even if there is no change in the sensor output. There is. In the above method, if the information transmitter side fails,
On the monitoring side, there is a big drawback that it is unknown whether information is not sent due to no sensor change or information does not come because a failure has occurred in the information transmitter.

(Objects of the Invention) The present invention solves the above-mentioned drawbacks, has immediacy for sensor operation, has a self-diagnosis function for line and device failures, and reduces battery consumption on the information transmitter side. The aim is to provide a telemetry system.

(Structure and Operation of the Invention) The wireless telemeter system of the present invention has the immediacy of sending the information immediately when the change of the sensor is detected, and the information transmitter side (monitored side) and the information receiver side ( Monitoring side)
The monitoring side has the time management of the self-diagnosis report of the line test including the communication equipment, and the self-diagnosis report is made by the activation of the information transmitter side.
The feature is that the actual down time of the information transmitter is lengthened by lengthening or shortening it depending on the situation such as at night, suppressing the battery consumption and operating without long-term battery replacement maintenance. And

That is, the wireless telemeter system of the present invention detects various states of the monitoring area by an information transmitter arranged in the monitoring area and wirelessly transmits the information, and receives radio waves from the information transmitter at a remote location. In a wireless telemeter system for remote monitoring by receiving at a device, the information transmitter transmits a detection unit that detects various states of a monitoring area and detection information obtained by the detection unit from the detection unit. A wireless transmission / reception unit that transmits wirelessly according to a request and receives return data from the information receiver, a battery power source that supplies power to each unit, and an on / off state of operation power supply from the battery power source to the wireless transmission / reception unit When the designated time set by the power saving circuit and the transmission request from the detection unit or the designation from the information receiver is reached, the power saving The power saving circuit when the time data indicating the specified time added to the return data from the information receiver is received by supplying the battery power to the wireless transmission / reception unit by turning on the power saving circuit. And a control unit that performs control for stopping the supply of power to the wireless transmission / reception unit, wherein the information receiver is the battery for the information transmitter when receiving a wireless signal from the information transmitter. The present invention is characterized by including a control unit for controlling the time data indicating the specified time determined to reduce the power consumption of the power source to be added with the return data and transmitted.

The structure and operation of the present invention will be described 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, reference numeral 1 is an information transmitter equipped with a sensor installed in a remote monitoring area, and transmits the information wirelessly at the same time as the occurrence of abnormal information from the sensor. Reference numeral 5 denotes an information receiver installed on the monitoring side. When receiving information from the information transmitter 1, the received information is returned to the information transmitter 1 again. 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 the coincidence with the transmission information. When the information receiver 5 receives the confirmation signal from the information transmitter 1, the information from the information transmitter 1 is first output to the monitoring unit 8 to display or sound an alarm to notify the observer. In this way, the observer can detect reliable local abnormality information.

On the other hand, in order to carry out the self-diagnosis of the line at a predetermined time interval, the timer value of the self-diagnosis signal sending timer is set and sent from the monitoring unit 8 to the information transmitter 1 via the information receiver 5. The information transmitter 1 confirms and sets the received timer value, and enters the power-off state (sleep mode). If no abnormal information is generated in the sensor of the information transmitter 1 for a long time, the transmitter / receiver of the information transmitter 1 is activated when the timer value set in the information transmitter 1 expires, and the line is abnormal. A self-diagnosis signal for confirming whether or not there is a (fault) is transmitted, communication with the information receiver 5 is executed, and if there is no abnormality, the sleep mode is entered again.

FIG. 2 is a block diagram showing details of a configuration example of the information transmitter 1 of FIG. In the figure, reference numeral 11 denotes a wireless transmission / reception unit, 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 _{DD2 is supplied} from the battery 20 via the power saving circuit 19.
The power saving circuit 19 is controlled by the control signal from the control unit (MPU) 18 so as to be activated and suspended, and is normally in a sleep state (sleep mode). Yes, the power to the wireless transceiver 11 is off.

Reference numeral 13 denotes a detection unit that detects a change in the state of the sensor. When a change (abnormality) occurs in one or more sensors, the number of the sensor that has changed and the state of the change are detected.

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

A programmable timer counter 15 is a timer value that prioritizes designation from the information receiver 5 on the monitoring side, or if there is no designation from the information receiver 5, waits until the timer value designated in the ID-ROM 17 is reached. It is a timer counter that counts and gives a start instruction to the control unit 18 when the time is up in any case, and is composed of a CMOS-IC and is in a constantly operating state with low power consumption.

Reference numeral 17 denotes an ID-ROM formed of an EEP-ROM, which stores an identification number unique to the information transmitter, a unique number given to each sensor of the detection unit 13, and other operation sequences of the information transmitter. It is a memory unit. Normally, the sleep mode is set, and the control unit 18 activates the sleep mode if necessary.

Reference numeral 18 denotes a control unit (processor unit) that executes operation control of the entire information transmitter 1. Normally, it is in sleep mode and interrupt activation command section 14 or programmable timer counter 15
Wake up and control operation is performed by the start command from.

_{Reference numeral} 19 denotes a power saving circuit (Power Saver) for supplying or stopping the operating power supply V _DD2 from the battery 20 to the wireless transmission / reception unit 11 having large power consumption under the control of the control unit 18.

Reference numeral 20 denotes a battery serving as an operation power source of the information transmitter 1, and a lithium primary battery or a solar battery and 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. The information receiver 5 installed on the monitoring side is always in a receiving operation state because it receives the radio waves transmitted from the information transmitter 1. In the figure, 51 is a wireless transmission / reception unit for performing wireless communication with the wireless transmission / reception unit 11 of the information transmitter 1. 53 is an ID-ROM composed of EEP-ROM
The memory unit stores an identification number unique to the information receiver, an operation sequence of the information receiver, and the like.
Reference numeral 54 is a control unit (microprocessor) that controls the entire device.

55 is an input / output unit (I / I) connected to check the abnormality detection information from the information transmitter 1 and then send it to the upper monitoring unit 8.
O).

Reference numeral 56 is a power supply unit that supplies the operating power of the entire device, and is composed of a voltage stabilization unit (Reg.) 561, an uninterruptible power supply unit 562, and a commercial power supply unit (Rec.) 563.

Next, the operation of the present invention will be described with reference to the flowcharts of FIGS.

FIG. 4 is a flow chart showing the operation of the information transmitter 1, and 101 to 120 show step numbers.

Normally, the detection unit 13, the programmable timer counter 15, and the time timer 16 of the information transmitter 1 always operate with extremely small power consumption, and the wireless transmission / reception unit 11 is in a sleep state.

When the detector 13 detects an abnormal signal from the sensor (10
1) Or when the self-diagnosis time t ₁ set in the programmable timer counter 15 is up (102), the power of all circuits including the power saving circuit 19 is turned on to be in an operating state (103).

For example, when a sensor such as a smoke detector, a temperature detector, or a gas detector detects an abnormality, the detection unit 13 is activated and the interrupt start command unit is activated.
An activation signal is applied to the control unit 18 from 14 to put the control unit 18 in the sleep mode into an operating state, give an operation power supply command to the power saving circuit 19, and supply operation power to the wireless transmission / reception unit 11 which consumes a large amount of power. And the power is turned on (10
3).

Step 104 is a process of setting the number N of times of collation and the number M of times of re-sending when communicating with the information receiver 5 in steps 113 to 119. In step 105, the number of the sensor which detected the abnormality and the abnormality information are collated with the contents of the ID-ROM 17 to encode the detection information and prepare as transmission data. In step 113 to 115, when the communication is not possible even after retransmitting M times after collating N times, the transmission code memory (step 120) stored inside the control unit 18 as temporary suspension is searched and prepared as transmission data. . Next, in step 106, communication is performed with the information receiver 5 through the control channel, a wireless empty channel is searched, and a wireless channel for data transmission / reception with the information receiver 5 is selected. Steps by selected radio channel
The transmission data prepared in 105 is transmitted. In step 108, data is transmitted and received the number of times (N times) set in step 104, and the transmitted code is collated with the returned data from the information receiver 5 to determine whether they match. And whether the information receiver 5 at the same time as the response data is specified in the self-diagnosis time t ₁ is determined in step 109, the value of t ₁ to the programmable timer counter 15 when a setting instruction of the timer value t ₁ is Simultaneously with the setting, the power is turned off (step 112) and the wireless transmission / reception unit 11 of the information transmitter 1 is set to the sleep mode.
The above operation returns to the initial normal state.

In this way, the information transmitter 1 is in the operating state only at any one of the transmission request when the sensor is abnormal and the self-diagnosis time t ₁ set in the programmable timer counter 15, and the self-diagnosis time t ₁ can be set from the information receiver 5, that is, the monitoring unit 8 side, by changing the self-diagnosis time depending on the need of security during daytime or nighttime. The consumption can be minimized.

Step 120 is a memory for storing the transmission data prepared in step 105 and the time of the time timer 16 when the code condition cannot be obtained due to the bad radio wave condition of the wireless line in step 108 by executing steps 113 to 119. This is a storage process for storing the data in the memory and retransmitting the data in the next transmission. That is, data is sent N times (three times in this example) for code matching in order to ensure the transmission information of the wireless line, and when the results of the code matching sending N times do not match, the matching sending is temporarily stopped,
Even if the retry for retransmitting is performed M times (three times in this example) after a predetermined time interval t ₂ (for example, t ₂ = 20 seconds), when the communication is not established, the data is stored.

The self-diagnosis timer value (t ₁ ) can be set by the monitoring unit 8 to 107 if necessary.
It is possible to arbitrarily set the time when the next self-diagnosis transmission is requested at the time of data communication.

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

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 the standby state for reception, and its operation is started depending on whether or not the information transmitter 1 has received the control channel (step 501). When a wireless channel for data communication is selected, it is next determined whether or not data is received (step 502). When the data reception is not good, the data reception is canceled after a predetermined time t _{3 and} the state returns to the initial state. If data is received, the received data is returned to confirm the received content, and at the same time, the self-diagnosis time (t ₁ ) is transmitted to the information transmitter 1 as necessary. Communication is performed N times, which is the number of times of transmission / reception collation set in the information transmitter 1, and the transmission data and the reception data are collated with each other, and when they match, the communication is terminated (steps 503 to 504).

In step 505, the presence or absence of self-diagnosis data is determined, and in steps 506 and 507, the communication data is transmitted to the monitoring unit 8. When the self-diagnosis time (t ₁ ) for the information transmitter 1 is specified in the communication data of step 503, steps 508, 509
Change the setting of the self-diagnosis timer value (t ₁ ) at, restart and return to the standby state. If no self-diagnosis signal is 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. To do.

If there is no abnormality in the sensor and no control channel is received for a long time, the line or information transmitter 1 is operated after a time (t ₁ ′) including a timer error from the self-diagnosis time (t ₁ ) previously designated in step 511. It is determined that some failure has occurred in the communication system of 1), and a failure report is transmitted to the monitoring unit 8 in step 512.

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

In this embodiment, the case where the information transmitter 1 and the information receiver 5 are one-to-one has been described, but it is also possible to monitor a plurality of information transmitters with one information receiver. Four
The retransmission timer value t ₂ shown in the example of the figure can be realized by providing a difference for each information transmitter to eliminate the overlap of wireless communication times.

(Effects of the Invention) As described in detail above, by implementing the present invention in a security monitoring device or the like, when a status monitoring sensor installed in a remote place detects an abnormality, it is immediately sent to the monitoring side. Since the power consumption of the battery of the information transmitter for reporting an abnormality can be reduced to the necessary minimum, the maintenance interval for battery replacement can be extended. In addition, the failure diagnosis of the line device can be automatically performed by the time designation from the monitoring side, which is extremely effective in improving the reliability of the abnormality information data.

[Brief description of drawings]

1 is a block diagram showing an example of the overall configuration of a wireless telemeter of the present invention, FIG. 2 is a diagram of a detailed configuration of an information transmitter of the present invention, and FIG. 3 is a diagram of a detailed configuration example of an information receiver of the present invention. Fourth
FIG. 5 is an operation flowchart of the information transmitter side of the present invention, fifth.
The figure is an operation flowchart of the information receiver side of the present invention. DESCRIPTION OF SYMBOLS 1 ... Information transmitter, 5 ... Information receiver, 8 ... Monitoring part, 11 ... Wireless transmission / reception part, 13 ... Detection part, 14 ... Interrupt activation instruction part, 15 ...
Programmable timer counter, 16 ... Time timer (clock section), 17 ... ID-ROM, 18 ... Control section (processor section), 19
… Power save circuit, 20… Battery, 51… Wireless transceiver, 53
... ID-ROM, 54 ... control section (processor section), 55 ... I / O (input / output section), 56 ... power supply section.

Claims (1)

[Claims] 1. An information transmitter arranged in a monitoring area detects various states of the monitoring area and wirelessly transmits the information, and a radio wave from the information transmitter is received by an information receiver provided in a remote place. In the wireless telemeter system that performs remote monitoring by means of the information transmitter, the information transmitter wirelessly receives a detection unit that detects various states of the monitoring area and detection information obtained by the detection unit from the detection unit. A wireless transmission / reception unit for transmitting and receiving return data from the information receiver, a battery power source for supplying power to each unit, and a power saving circuit for turning on / off operation power supply from the battery power source to the wireless transmission / reception unit, When the designated time set by the transmission request from the detection unit or the designation from the information receiver is reached, the power saving circuit is turned on and the radio When the battery power is supplied to the transmitter / receiver and the 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 supply power to the wireless transmitter / receiver. And a control unit for performing control for stopping the supply, wherein the information receiver reduces the power consumption of the battery power source to the information transmitter when receiving a wireless signal from the information transmitter. 2. A wireless telemeter system, comprising: a control unit for controlling so that the time data indicating the specified time defined in 1 above is added to the return data and transmitted.