JP2005085131A - Wireless security system, detector thereof, and control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wireless security system for suppressing jamming of a signals, even if the signal is transmitted from a management device to a plurality of detectors. <P>SOLUTION: The wireless security system comprises the management device 11 for transmitting a plurality of signals, where each different ID is added wirelessly; and a plurality of detectors 12 that retain each inherent ID and specific timing information, receives a signal where the inherent ID is added, in a plurality of signals in which the ID transmitted from the management device 11 is added, and transmits the signal where the specific ID is added to the management device 11 wirelessly, at a timing based on the specific timing information. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a wireless security system that transmits and receives signals between a management device and a detection device, a detection device, and a control method thereof.

Security systems used in homes and offices install multiple detection devices indoors such as homes and offices, collect information detected by the sensors of each detection device with a management device, and perform centralized management doing. Each detection device incorporates an ID, and the command is transmitted from the management device, and the ID is specified. When the management device collects information from the detection device, the management device transmits a transmission command specifying the ID, and the detection device incorporating the specified ID transmits the detection information as a report reply. In this case, if the detection information is not transmitted from the detection device incorporating the specified ID within a predetermined waiting time, the management device alarms the abnormality of the detection device and ends the information collection work. Transmission and reception between the management device and the detection device are performed by serial communication. This type of security system is described in Patent Document 1.
JP-A-6-229154 (2nd to 4th pages)

  When a command is transmitted from a management device with a plurality of IDs specified, a plurality of responses are transmitted, which causes a problem in that interference occurs and information such as an abnormality cannot be collected.

  The present invention has been made to solve the above-described problems, and even when a signal is transmitted from a management device to a plurality of detection devices, a wireless security system capable of suppressing signal interference, and its An object is to provide a detection device and a control method.

In order to achieve the above-described object, one aspect of the wireless security system of the present invention includes a management device that wirelessly transmits a plurality of signals each having a different ID added thereto,
A unique ID and unique timing information are held, and a signal with the unique ID is received from among a plurality of signals with the ID transmitted from the management apparatus, and based on the unique timing information. A plurality of detection devices that wirelessly transmit a signal with the unique ID added thereto to the management device;
It has.

Further, one aspect of the control method of the wireless security system of the present invention is a step of switching the detection device holding the unique ID and timing information to the reception mode,
Determining whether the signal added with the ID transmitted from the management device is a transmission command for the detection information of the detection device;
When the signal with the ID added is a transmission command, determining whether the unique ID of the detection device, the unique ID, and the ID transmitted from the management device match,
If the unique ID and the transmitted ID match, start counting a timer in the detection device;
Reading detection information by a sensor in the detection device;
In connection with the timing based on the timing information, switching the detection device to a transmission mode;
Transmitting the detection information with the unique ID of the detection device to the management device;
It has.

  According to the present invention, signal interference can be suppressed even when signals are transmitted from the management device to a plurality of detection devices.

(First embodiment)
A wireless security system according to the first embodiment of the present invention will be described with reference to FIGS. FIG. 1 schematically shows a configuration of a wireless security system according to the present embodiment. This security system includes a management device 11 and a detection device 12. The management device 11 has a built-in power supply 13, and power is supplied from the power supply 13 to the management control device 14. The management control device 14 transmits a transmission command to transmit the current information to the detection device 12 via the antenna 15. Identification information (hereinafter referred to as “ID”) is specified in the command transmitted from the management device 11, and each detection device 12 includes a unique ID and unique timing information respectively in the ID holding circuit 18 and the detection. Are held in the control device 17. The detection device 12 includes a power supply 16, and power is supplied from the power supply 16 to the detection control device 17 and the ID holding circuit 18. The detection control device 17 receives the transmission command transmitted from the management device 11 via the antenna 19 and collates the ID held in the ID holding circuit 17 with the ID specified by the command. . For the current external information of the detection device 12, the output of the sensor 20 is read and a report is transmitted to the management device 11.

  In this security system, as shown in FIG. 2, a management device 11 and a plurality of detection devices 12 are arranged indoors. Since communication between the management device 11 and the plurality of detection devices 12 is performed wirelessly, no wiring is necessary.

  The operation flow of the detection apparatus 12 when receiving a transmission command from the management apparatus 11 and transmitting the detected detection information will be described with reference to FIG.

First, in step S1, the detection device 12 switches itself to the reception mode, stops power supply to the sensor control circuit 25 and the sensor 20 shown in FIG. 4 to be described later, sets the counter to “0”, etc. Set initial conditions. Next, in step S <b> 2, it is determined whether a transmission command related to detection information has been received from the management device 11. If received, in step S3, the ID held in the ID holding circuit 18 is collated with the ID specified by the command. As a result, if the IDs do not match, it is not a command for itself, so the command is ignored and the next command is awaited without doing anything. On the other hand, if the IDs coincide with each other, it is an instruction for the user, and therefore, in step S4, a timer is started that will be described later after being incorporated in the detection control device 17. Each timer of each detection device 12 holds unique timing information. The timing information is information related to transmission / reception timing, for example, a response time t seconds from when a transmission command is received to when a report is transmitted. Subsequently, in step S5, power is supplied to the sensor control circuit 25 and the sensor 20 shown in FIG. 4 to be described later, and predetermined circuits are operated so as to satisfy voltage conditions and current conditions determined for each sensor. And set the measurement conditions. In step S6, the output of the sensor 20 in the detection device 12 is read. The output information of the sensor 20 is transmitted to the management device 11 as detection information together with the ID of the detection device 12. In step 7 (S-7), it is determined whether or not the response time t seconds in the timing information has been exceeded. When timing t has come, the detection device 12 is switched to the transmission mode in step S8, and then in step S9. Then, the detection information is transmitted to the management device 11 via the antenna 19.
After the transmission, the detection device 12 is again switched to the reception mode, the power of the circuit in the detection control device 17 is turned off (or standby), and the next command is awaited. The power sources 13 and 16 have AC100V power lines, batteries, batteries, and the like. However, when batteries or batteries are used, no wiring is required. Therefore, when a battery or a battery is used, it is preferable because the management device 11 and the detection device 12 can be installed at an arbitrary place. In addition, although the capacity of batteries and batteries is limited, turning the circuit power off (or standby) while waiting for the next command is effective in saving power and extending the life of the power supply. it can. The reception determination (S2) and the ID verification (S3) can be performed by changing the order.

  FIG. 4 is a block diagram of the detection control device 17 in the detection device 12 shown in FIG. The detection device 12 is switched to the reception mode by the transmission / reception switching circuit 21, and reads the transmission command from the management device 11 by the reception circuit 22 via the antenna 19 and the transmission / reception switching circuit 21. The read signal is sent to the ID collation circuit 23 and collates the ID held in the ID holding circuit 18 with the ID specified by the command. If the IDs match, the timer 24 starts counting, and at the same time, a signal is sent to the sensor control circuit 25. The sensor control circuit 25 sets measurement conditions for the sensor 20, and output information composed of sensor output measurement results is sent to the transmission data synthesis circuit 26. The ID held in the ID holding circuit 18 is also sent to the transmission data combining circuit 26 in the same manner. When the timer 24 finishes counting, the transmission data synthesis circuit 26 synthesizes the ID obtained from the ID holding circuit 18 and the output information of the sensor and sends it to the transmission circuit 27 as detection information. At the same time, the transmission / reception switching circuit 21 is switched to the transmission mode. The detection information sent to the transmission circuit 27 is transmitted to the management apparatus 11 via the transmission / reception switching circuit 21 and the antenna 19.

  FIG. 5 shows a circuit example of the ID verification circuit 23 shown in FIG. Although the ID is described in 4 bits for simplification, since each detection device 12 needs to have a unique ID, the number of ID bits is a binary number corresponding to the number of detection devices 12. It is necessary to be provided so as to cover. As shown in FIG. 5, a serial-in / parallel-out shift register 31 is provided, and a data signal and a clock signal of a transmission command from the receiving circuit 22 are input. These signals are input to the data input terminal DT and the clock input terminal CK of the shift register 31. When a signal related to the ID specified by the transmission command is received from the receiving circuit 22 to the data input terminal, the ID of the ID holding circuit 18 is compared with the ID specified by the transmission command. This comparison is performed by the four exclusive OR circuits 32. The exclusive OR circuit 32 compares two input signals, and outputs “0” if the two input signals are the same, and outputs “1” to the sensor control circuit 25 or the like if they are different. That is, if all four bits match, the four exclusive OR circuits 32 all output “0”. All outputs of the four exclusive OR circuits 32 are input to the NOR circuit 33. The NOR circuit 33 compares a plurality of input signals, and outputs “1” as the output Q when all the input signals are “0”. Therefore, if the IDs match all 4 bits, '1' is output.

  Next, FIG. 6 shows a circuit example of the sensor control circuit 25 shown in FIG. The sensor 20 includes a phototransistor 41 shown in FIG. 6, and the base of the phototransistor 41 is connected to a light receiving device (not shown) of the sensor 20. The collector of the phototransistor 41 is connected to the input terminal of the sensor control circuit 25, connected to the power supply via the resistor 42, and connected to the base of the transistor 43. The emitter of the phototransistor 41 is grounded to the ground in the sensor control circuit 25. The collector of the transistor 43 is connected to the output terminal of the sensor control circuit 23, is connected to the power supply via the resistor 44, and the emitter is grounded. The signal output from the output terminal of the sensor control circuit 25 is sent to the transmission data synthesis circuit 26.

  Next, the operation of the sensor control circuit 25 will be described. Generally, in the phototransistor 41, current does not flow between the collector and the emitter unless light is received, but current flows when light is received. In general, in the transistor 43, when a base current flows from the base to the emitter, the transistor is turned on, and a current larger by one digit or more than the base current flows between the collector and the emitter.

  First, consider a case where light does not enter the phototransistor 41. In this case, since no current flows between the collector and the emitter of the phototransistor 41, the current passing through the resistor 42 flows directly into the base of the transistor 43. When a current flows into the base of the transistor 43, the transistor 43 is turned on and a current flows between the collector and the emitter. Therefore, a large current flows through the resistor 44, and the collector potential of the transistor 43 becomes close to '0V'. Therefore, the signal output from the output terminal of the sensor control circuit 25 is a signal close to “0”.

  On the other hand, consider the case where light enters the phototransistor 41. In this case, since a current flows between the collector and the emitter of the phototransistor 41, the current via the resistor 42 does not flow into the base of the transistor 43 but flows to the ground. Therefore, no current flows between the collector and emitter of the transistor 43, and the collector potential becomes close to the power supply potential. Therefore, the signal output from the output terminal of the sensor control circuit 25 is a signal close to “1”.

  Next, FIG. 7 shows a circuit example of the transmission data synthesis circuit 26 shown in FIG. As shown in FIG. 7, it has a parallel-in / serial-out shift register 51 to which output signals from the ID holding circuit 18 and the sensor control circuit 25 are inputted. These output signals are input to the A, B, C, D, and E input terminals of the shift register 51. Further, when the input signal “0” is input to the load input terminal L, the shift register 51 can capture and hold the signal. Further, when an input signal “1” is input to the load input terminal L and a pulse is input to the clock input terminal CK, the input terminals E, D, C, B, A are synchronized with the rising timing of the pulse. The captured signals are output from the QE output terminal in that order. That is, the signals A, B, C, and D representing ID and the output signal of the sensor 20 are output in this order. As described above, when the output signal of the sensor 20 is stored and five pulses are input to the clock input terminal CK when the timer 24 finishes counting, the ID and the output information of the sensor 20 are output to the transmission circuit. .

  Next, FIG. 8 illustrates an operation flow of the management device when a transmission command is transmitted to the detection device and detection information detected by the detection device is received.

First, in step S21, an operator or a device that controls the management apparatus 11 switches the management apparatus 11 to the transmission mode. Thereby, in step S <b> 22, the management device 11 transmits a detection information transmission command to the detection device 12. An ID is specified in the transmission command. After transmitting the transmission command, in step S23, the mode is switched to the reception mode and the detection information report from the detection device 12 is awaited. In step S24, it is determined whether a predetermined waiting time has been exceeded. If not, it is determined in step S25 whether detection information has been obtained. Here, the predetermined waiting time is a time set for waiting for a measurement result report from the sensor, for example, 0.3 seconds. If the detection information has not been obtained, the process returns to S24 to determine whether a predetermined waiting time has been exceeded. If the detection information is obtained, ID verification is performed in step S26 in order to determine whether or not the report is from the detection device 12 that issued the command. If it does not match the ID of the detection device 12 that issued the command, the report is ignored and the detection information report of another detection device 12 is awaited. If there is no report even after the predetermined waiting time has passed, in step S27, an alarm is given to the abnormality of the detection device 12 that issued the command, and the information collection operation at that time is terminated. Alternatively, if there is no report even after a predetermined waiting time has elapsed, the same transmission command may be transmitted to the same detection device 12 again or again, and the report may be waited for. If there is no report from the detection device even for the transmission command again or again, in step S27, an abnormality of the detection device 12 that issued the command is warned, and the information collection operation at that time is terminated. If the ID matches the ID of the detection device 12 that has issued the command, it is stored in the management device 11 as collected detection information, and is used in an information management operation using the management device 11 by the operator.

  FIG. 9 is a block diagram of the management control device 14 in the management device 11 shown in FIG. When transmitting a transmission command to the detection device 12, first, the central control circuit 61 sends a signal attached with a predetermined ID to the transmission circuit 62. Subsequently, the transmission / reception switching circuit 63 switches the management apparatus 11 to the transmission mode, and transmits a transmission command via the antenna 15. After transmitting the transmission command from the management device 11, the mode is switched to the reception mode, and a report from the detection device 12 with the specified ID is awaited. When the detection information from the detection device 12 is transmitted, the signal is read by the reception circuit 64 via the antenna 15 and the transmission / reception switching circuit 63. The read signal is sent to the centralized control circuit 61, where it is determined whether the ID is designated by the command, and is stored in the centralized control circuit 61 as collected detection information.

According to the present embodiment, when a transmission command specifying an ID is transmitted from the management device 11 to the detection device 12, the detection information 12 is transmitted based on the timing information determined by each detection device 12. FIG. 10 shows transmission timings of transmission signals of the management device 11 and the plurality of detection devices 12 (each detection device is displayed as 12a and 12b). The response time of timing information (for example, t ₁ second or t ₂ seconds) is held in each detection device, and the detection information transmitted from the transmission circuit starts the timer after collating the ID, Sent after timing.

Even when transmission commands specifying a plurality of IDs are simultaneously transmitted from the management device to the detection device, detection information is reported based on timing information determined by the individual detection devices. FIG. 11 shows transmission timings of transmission signals of the management device 11 and the detection device 12 (each detection device is displayed as 12a, 12b, 12c, 12d, and 12e). The detection information transmitted from the transmission circuit waits for a response time (for example, t ₁ second, t ₂ seconds, t ₃ seconds, t ₄ seconds, t ₅ seconds) of timing information determined by each detection device, Sent.

  That is, the detection information transmitted from the transmission circuit is transmitted after waiting for the response time of the timing information determined by each detection device. Therefore, the detection information is transmitted for each detection device with the specified ID. Since they are different, interference can be suppressed. Further, information such as abnormality of a predetermined detection device can be collected more reliably.

(Second Embodiment)
12 to 16 show a wireless security system according to the second embodiment of the present invention. The arrangement of the management device 71 and the plurality of detection devices 72 is the same as the arrangement of the first embodiment described above. As shown in FIG. 12, the management device 71 includes a power source 73, and power is supplied from the power source 73 to the management control device 74. The management control device 74 transmits a transmission command to report the current information to the detection device 72 via the antenna 75. Identification information (hereinafter referred to as “ID”) is specified in the command transmitted from the management device 71, and each detection device has a unique ID and unique timing information. The detection device 72 includes a power supply 76, and power is supplied from the power supply 76 to the detection control device 77 and the ID holding circuit 78. The detection control device 77 receives the transmission command transmitted from the management device 71 via the antenna 79, and collates the ID held in the ID holding circuit 78 with the ID specified by the command. . For the current information of the detection device 72, the output of the sensor 80 is read and reported to the management device 71.

  The ID and timing information can be rewritten by a writing circuit 81 using a nonvolatile memory in accordance with a change command from the management device. When changing the ID, the ID in the ID holding circuit is changed. When changing the timing information, for example, the response time of the timing setting circuit in the timer described later is changed. The ID and timing information are set and changed so as to differ depending on each detection device indoors such as in a home or office.

  The operation flow of the detection device 72 when receiving the transmission command from the management device 71 and transmitting the detected detection information is the same as the operation flow (FIG. 3) of the first embodiment described above. The operation flow of the management device 71 when transmitting a transmission command to the detection device and receiving the detection information detected by the detection device 72 is the same as the operation flow (FIG. 8) of the first embodiment described above. It is.

  FIG. 13 shows an operation flow of the detection device 72 when an ID change command is received from the management device 71 and the ID is changed.

  First, in step S31, the detection device 72 switches itself to the reception mode, stops power supply to the sensor control circuit 95 and the sensor 80 shown in FIG. 15, which will be described later, and sets the counter to “0”. Set initial conditions. Next, in step S32, the ID held in the ID holding circuit 78 is collated with the ID specified by the command. As a result, if the IDs do not match, it is not a command for itself, so the command is ignored and the next command is awaited without doing anything. On the other hand, if the IDs coincide with each other, it is an instruction for the user, and therefore, in step S33, it is determined whether or not an instruction to change the ID of the detection apparatus has been received from the management apparatus 71. If received, in step S34, the writing circuit 81 is used to write a new ID to the ID holding circuit. If the ID change command is not received, the command operation is performed in step S35.

  FIG. 14 shows an operation flow of the detection device 72 when the timing information change command is received from the management device 71 and the timing information is changed.

  First, in step S41, the detection device 72 switches itself to the reception mode, stops power supply to the sensor control circuit 95 and the sensor 80 shown in FIG. 15 to be described later, sets the counter to “0”, etc. Set initial conditions. Next, in step S42, the ID held in the ID holding circuit 78 is collated with the ID specified by the command. As a result, if the IDs do not match, it is not a command for itself, so the command is ignored and the next command is awaited without doing anything. On the other hand, if the IDs coincide with each other, it is a command for itself, and therefore, in step S43, it is determined whether or not a command for changing the timing information of the detection device has been received from the management device 71. If received, in step S44, the write circuit 81 is used to write new timing information to the timing setting circuit in the timer. If the timing information change command is not received, the command operation is performed in step S45.

FIG. 15 is a block diagram of the detection control device 77 in the detection device 72 shown in FIG. The detection device is switched to the reception mode by the transmission / reception switching circuit 91, and the command from the management device is read by the reception circuit 92 via the antenna 79 and the transmission / reception switching circuit 91. The read signal is sent to the ID collation circuit 93 and collates the ID held in the ID holding circuit 78 with the ID specified by the command. If the IDs match, the command operation is determined, and if it is an ID change command, the command is sent to the writing circuit 81 using a nonvolatile memory, and the ID held in the ID holding circuit 78 is rewritten. If the command operation is a timing information change command, the command is sent to the writing circuit 81 using the nonvolatile memory, and the response time set in the timing setting circuit in the timer 94 is rewritten. The operation flow of the detection apparatus when reporting the transmission command from the management apparatus is the same as that in the first embodiment, and the phototransistor 101, sensor control circuit 95, transmission data synthesis circuit 96, transmission As the circuit such as the circuit 97, a circuit having the same configuration as that of the first embodiment can be used.

  In this embodiment, the ID and timing information of each detection device can be changed based on a change command from the management device. Therefore, when each detection device is purchased, the ID and timing information are '0000' and It may be set to '0'. FIG. 16 shows an operation flow when changing the ID when each detection device is purchased and the ID is “0000”, that is, not set.

  First, in step S51, the operator turns on the detection device. Insert the battery and battery or insert the power plug into the household power supply. In step S52, the operator designates ID “0000” from the management apparatus and transmits an ID change command. Subsequently, in step S53, the detection device receives the ID change command and changes the ID.

  Thus, at the time of manufacturing (at the time of purchase), since the ID and timing information are not different for each detection device, the manufacturing process can be standardized, the throughput can be improved, and the cost can be reduced.

In addition, according to the present embodiment, since the ID and timing information of each detection device can be changed based on a change command from the management device, the detection device is installed indoors such as in a home or office. Thus, it is possible to set each unique ID and timing information. In other words, depending on the number of detection devices placed indoors,
Since the timing information can be set, the number of ID bits can be set to the minimum, and the response time of the timing information can be set to the minimum. Therefore, the transmission data creation circuit and the ID verification circuit can be simplified, and the detection device can be downsized. In addition, transmission / reception time can be shortened.

  Furthermore, according to the present embodiment, when a transmission command specifying an ID is transmitted from the management device to the detection device, the detection information is transmitted based on timing information determined by each detection device. Therefore, even when a detection device that holds an ID different from the designated ID makes a mistake, the detection information is transmitted at different timings, so that interference is unlikely to occur. Further, information such as abnormality of a predetermined detection device can be collected more reliably.

  In addition, even when transmission commands specifying a plurality of IDs are transmitted from the management device to the detection device at the same time, detection information is reported based on timing information determined by each detection device. Therefore, since the timing at which detection information is transmitted differs for each detection device with the specified ID, interference is unlikely to occur. Further, information such as abnormality of a predetermined detection device can be collected more reliably.

  The rewritable nonvolatile memory is, for example, PROM (Programmable ROM), OTP (One Time PROM), EEPROM (Electric Erasable PROM), Flash EEPROM, Ntime PROM, FUSE ROM, etc., and is not particularly limited.

It is a block diagram which shows the outline | summary of the wireless security system which concerns on the 1st Embodiment of this invention. It is a figure which shows the arrangement | positioning state indoors of the wireless security system which concerns on the 1st Embodiment of this invention. It is a figure which shows the operation | movement flow of a detection apparatus when transmitting the detection information of the wireless security system which concerns on the 1st Embodiment of this invention. It is a block diagram of a control device for detection in a detection device of a wireless security system concerning a 1st embodiment of the present invention. It is a figure which shows the ID collation circuit in the control apparatus for a detection of the detection apparatus of the wireless security system which concerns on the 1st Embodiment of this invention. It is a figure which shows the sensor control circuit in the control apparatus for a detection of the detection apparatus of the wireless security system which concerns on the 1st Embodiment of this invention. It is a figure which shows the transmission data synthetic | combination circuit in the control apparatus for a detection of the detection apparatus of the wireless security system which concerns on the 1st Embodiment of this invention. It is a figure which shows the operation | movement flow of a management apparatus when receiving the detection information detected with the detection apparatus of the wireless security system which concerns on the 1st Embodiment of this invention. It is a block diagram of the management control device in the management device of the wireless security system according to the first embodiment of the present invention. It is a figure which shows the transmission timing of the transmission signal of the management apparatus and detection apparatus of a wireless security system which concerns on the 1st Embodiment of this invention. It is a figure which shows the transmission timing of the transmission signal of the management apparatus of the radio | wireless security system which concerns on the 1st Embodiment of this invention, and a some detection apparatus. It is a block diagram which shows the outline | summary of the wireless security system which concerns on the 2nd Embodiment of this invention. It is a figure which shows the operation | movement flow of a detection apparatus when changing ID of the detection apparatus of the wireless security system which concerns on the 2nd Embodiment of this invention. It is a figure which shows the operation | movement flow of a detection apparatus when changing the timing information of the detection apparatus of the wireless security system which concerns on the 2nd Embodiment of this invention. It is a block diagram of the control apparatus for detection in the detection apparatus of the wireless security system which concerns on the 2nd Embodiment of this invention. It is a figure which shows the operation | movement flow with respect to a management apparatus and a detection apparatus when changing ID, when ID of the detection apparatus of the wireless security system which concerns on the 2nd Embodiment of this invention is not set.

Explanation of symbols

11, 71 Management device 12, 72 Detection device 13, 16, 73, 76 Power supply 14, 74 Management control device 15, 19, 75, 79 Antenna 17, 77 Detection control device 18, 78 ID holding circuit 20, 80 Sensor 21, 91 Transmission / reception switching circuit 22, 92 Reception circuit 23, 93 ID verification circuit 24, 94 Timer 25, 95 Sensor control circuit 26, 96 Transmission data synthesis circuit 27, 97 Transmission circuit 31, 51 Shift register 32 Exclusive OR circuit 33 NOR circuit 41, 101 Phototransistor 42, 44 Resistor 43 Transistor 61 Centralized control circuit 62 Transmission circuit 63 Transmission / reception switching circuit 64 Reception circuit 81 Write circuit

Claims (14)

A management device for wirelessly transmitting a plurality of signals each having a different ID added thereto;
A unique ID and unique timing information are held, and a signal with the unique ID is received from among a plurality of signals with the ID transmitted from the management apparatus, and based on the unique timing information. A plurality of detection devices that wirelessly transmit a signal with the unique ID added thereto to the management device;
A wireless security system.   The wireless system according to claim 1, wherein the management device wirelessly receives signals from the plurality of detection devices at different timings when transmitting a plurality of signals to which the unique IDs are added. Security system.   The plurality of detection devices, when receiving a signal added with a plurality of the unique IDs, wirelessly transmit signals to the management device at different timings, respectively. The described wireless security system.   4. The wireless system according to claim 1, wherein the detection device includes an ID holding circuit that holds the unique ID, and a timer that controls the timing of transmission. 5. Security system. The detection device includes an ID holding circuit that holds the unique ID, a timer that controls the timing to be transmitted, a writing circuit that changes the timing of the ID held in the ID holding circuit and the timing information,
4. The wireless security system according to claim 1, wherein the wireless security system is provided. An antenna capable of transmitting and receiving a signal with an ID added thereto;
A transmission / reception switching circuit for switching between transmission and reception modes;
A receiving circuit for receiving a signal from the antenna via the transmission / reception switching circuit;
An ID holding circuit for holding a unique ID;
An ID collation circuit for collating the unique ID held in the ID holding circuit with the ID added to the signal received by the receiving circuit;
A sensor to detect,
A transmission data combining circuit that generates detection information obtained by combining the result detected by the sensor and the ID held in the ID holding circuit;
A transmission circuit for transmitting a signal comprising the detection information;
A timer for controlling the transmission circuit and the transmission / reception switching circuit so as to hold unique timing information and transmit the detection information at a timing based on the timing information;
An apparatus for detecting a wireless security system comprising:   The wireless security system detection device according to claim 6, wherein the signal to which the ID is added is a transmission command for requesting transmission of external information obtained by the sensor.   The wireless security system detection device according to claim 6, further comprising a writing circuit that changes the timing of the ID and the timing information held in the ID holding circuit. The signal to which the ID is added is a transmission command for requesting transmission of external information, or a change command for requesting to change the ID or the timing information unique to the detection device. The detection device for a wireless security system according to claim 8. Switching the detection device holding the unique ID and timing information to the reception mode;
Determining whether the signal added with the ID transmitted from the management device is a transmission command for the detection information of the detection device;
When the signal with the ID added is a transmission command, determining whether the unique ID of the detection device, the unique ID, and the ID transmitted from the management device match,
If the unique ID and the transmitted ID match, start counting a timer in the detection device;
Reading detection information by a sensor in the detection device;
In connection with the timing based on the timing information, switching the detection device to a transmission mode;
Transmitting the detection information with the unique ID of the detection device to the management device;
A control method for a wireless security system comprising: Switching the management device to transmission mode;
A step of transmitting a transmission command from the management device with respect to detection information of the detection device by adding a unique ID of the detection device;
After transmitting the transmission command, switching the management device to a reception mode;
Determining whether a predetermined waiting time has been exceeded;
If the waiting time has not been exceeded, determine whether the detection information has been received, and if received, determine whether the detection information has an ID that matches the ID,
If the waiting time is exceeded, warning the abnormality of the detection device holding the ID;
A control method for a wireless security system comprising: If the predetermined waiting time is exceeded,
Switching the management device to transmission mode again;
A step of transmitting a transmission command from the management device to the detection information of the detection device again by adding a unique ID of the detection device, and
After transmitting the transmission command, switching the management device to the reception mode again;
Perform the step of determining again whether the predetermined waiting time has been exceeded,
The method of controlling a wireless security system according to claim 11, further comprising a step of alarming an abnormality of the detection device incorporating the ID when the predetermined waiting time is exceeded even if the determination is made. Switching the management device to transmission mode;
A step of transmitting a transmission command from the management device for each detection information of a plurality of detection devices, adding a unique ID of each of the detection devices, and
After transmitting the transmission command, switching the management device to a reception mode;
Determining whether a predetermined waiting time has been exceeded;
If not, it is determined whether the detection information is received, and if received, the detection information to which an ID that matches one of the IDs added when transmitting a transmission command is added Determine whether
If exceeding, the step of alarming abnormality of the detection device having the ID that did not receive the detection information among the IDs added when transmitting the transmission command;
A control method for a wireless security system comprising: Switching the detection device holding the unique ID and timing information to the reception mode;
Determining whether the ID added to the signal transmitted from the management device matches the unique ID of the detection device;
When the added ID and the unique ID match, determining whether the signal is a change command for the ID or timing information of the detection device;
If it is an ID change command, the write circuit changes the ID held in the ID holding circuit of the detection device;
If the timing information change command, the writing circuit to change the timing information held in the timer of the detection device;
A control method for a wireless security system comprising:

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