DE20308426U1 - Multiprocessor alarm - Google Patents

Description

Applicant:

Yi-Chia Liao

No. 47, Lane 93,

Nioupu S. Rd., Hsinchu City,

Taiwan R.O.C.

Multiprocessor alarm system Area: of invention

The present invention relates to an alarm system or alarm system device and in particular to a multi-processor alarm system comprising a plurality of detection processors each separately connected to a radio alarm device and a radio assistance system by means of radio signals.

Background of the invention

Conventional alarm systems, such as the one shown in Fig. 1, generally have a plurality of sensors 2 installed at locations where burglars might break in, and a receiver processor 1 located at a selected position. In such an alarm system, the receiver processor 1 must be installed at a fixed location. Because installation of the receiver processor 1 must take into account the possibility of it being sabotaged, it must be located in a secret or hidden area. The reason for this is that once the receiver processor 1 is damaged, all the sensors 2 are ineffective and become useless. Because the receiver processor 1 is in a hidden location

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has to be installed, the operation by a user and the maintenance or repair becomes laborious.

In addition, the size of the receiver processor 1 and the sensors 2 is quite bulky. Except for certain selected locations, they are not portable. In the event of natural disasters (e.g. earthquakes, power failures, floods, avalanches, fires or the like), they also do not offer any assistance or contingency functions.
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Summary of the invention

It is therefore an object of the present invention to provide a multi-processor alarm system which has a plurality of detection processors. At least one detection processor is located in a respective detection area. Each detection processor is separately connected to a radio alarm device and a radio assistance system using radio signals.

Another object of the invention is to provide a help function in case natural disasters occur. Since each detection area has a detection processor, users can easily access the detection processor and use the functional input interface to request external assistance.

The foregoing and other objects, features and advantages of the invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings.

Short description of the drawings

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Fig. 1 is a structural layout of a conventional alarm system.

Fig. 2 is a perspective view of the present invention.

Fig. 3 is a block diagram of the control circuit according to the present invention.

Figs. 4 to 4J are circuit diagrams according to the present invention.

Fig. 5 is a structural layout according to the present invention.

Detailed description of the preferred embodiment

Referring to Fig. 2, the multiprocessor alarm system according to the invention comprises at least one detection processor 10 installed on or at each detection area T. A plurality of the detection processors 10 are organized to form the alarm system device of the invention. Each detection processor 10 has a housing surface which includes:

a numeric input interface 11 to enter or set passwords to enable or reset the alarm of the detection processor 10, a functional input interface 12, a display interface 13, an alarm indicator light 14, an indicator light 15, a detection device 16 and a switch 17.

The detection device 16 includes:

an infrared light sensor 160 (this can be an infrared light sensor for a human body) to automatically detect the temperature of a human body or motion signals, a photosensitive sensor 161 to automatically detect a brightness of light sources. The switch 17 is used to switch the detection device

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device 16 on or off, and the alarm indicator light 14 will then illuminate when the switch 17 is activated.

The functional input interface 12 includes:
a lighting button 120, a luminous button or fluorescent button 121, a flash button 122, a time button 123, a power failure lighting button 124, an automatic lighting button 125, an automatic language selection button 126 and an SOS button 127.

Also referring to Figures 3 and 4 to 4J, the detection processor 10 includes a control circuit 20 having a first control unit 21 and a second control unit 22. The first control unit 21 includes:

an infrared light sensor unit 201 for receiving signals from the infrared light sensor and for sending detection signals to a microprocessor unit 204, which in turn sends signals to a radio broadcasting unit or radio signal transmitting unit 206, a storage unit 203 for storing a signal status from other units, for example, password signals from an operating unit 202 or detected signals from the infrared light sensor unit 201, the microprocessor unit 204 which processes and controls the signals from other units and compares the passwords entered by the operating unit 202 with the password signals stored in advance in the storage unit 203 to effect decoding, the radio transmitting unit 206 which sends the signals (for example, the alarm status and data) processed by the microprocessor unit 204 to a radio alarm device 30 and a radio assistance system 40 using radio signals, and a backup power supply 210 which provides a backup power supply for the control circuit 20 in the event of a power failure. A charging unit 213 is provided for electrical charging.

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The second control unit includes: a photosensitive detection unit 200 for receiving signals detected by the photosensitive sensor 161 and for sending the signals to the microprocessor unit 204, which in turn outputs signals to a lighting unit 208, the operation unit 202 for inputting entered password signals to the microprocessor unit 204 to release the alarm state of the detection processor 10, a display unit 207 for receiving operation and status signals provided by the microprocessor unit 204 and for displaying the signals on the display interface 13, the lighting unit 208 which receives the signals from the microprocessor unit 204 to determine whether the light sources should be turned on or off and to adjust a light brightness, an alarm unit 209 which receives signals from the microprocessor unit 204 and sends signals to an alarm indicator light 14, a speaker unit 211 which receives signals from the microprocessor unit 204 and generates an alarm sound to alert or warn operators, and an SOS help unit 212 which receives signals from the SOS button 127 and outputs signals to the microprocessor unit 204 so that the microprocessor unit 204 can generate Morse codes for the lighting unit 208, the loudspeaker unit 211 and the radio broadcasting unit 206.

Referring to Figures 2, 3 and 5, due to the above design, the multiprocessor alarm system of the invention can achieve the following effects:
1. Each detection area T has at least one detection processor 10 and a plurality of the detection processors 10 form the multi-processor alarm system. And each detection processor 10 is separately connected to the radio alarm device 30 and the radio assistance system 40 by means of radio wave radiation. When burglars break in and are detected by the infrared light sensor 160

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, the microprocessor unit 204 of the control circuit 20 sends signals to the wireless alarm device 30 and the wireless assistance system 40 using radio signals to achieve the goal of preventing burglaries. It should be noted that even if the intruder discovers and disables the detection processor 10 in one detection area T, the detection processors 10 in the remaining detection areas T are still operational and can continuously perform detection. In addition, when the detection processor 10 is disabled, the detection signals have already been sent to the wireless alarm device 30 and the wireless assistance system 40. This is a significant difference from the conventional alarm systems. Because conventional alarm systems usually have a plurality of sensors 2 arranged in each detection area and because a single processor 1 receives the detected signals from the sensors 2 and processes the αλειδαιαια. arm and assistance systems 3 and 4 are activated, once the processor 1 has been put out of operation, all sensors 2 used in the building are useless.

2. The detection processor 10 according to the invention has a backup power supply 210. A power failure is therefore not a cause for concern. In addition, users can easily reset and release the alarm status password via the numeric input interface 11 of the detection processor 10. Thus, the detection processor 10 can be installed anywhere users wish without the need to hide the detection processor. As soon as the detection processor 10 detects intruders, a preset audible alarm is generated and light is projected or emitted.

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to deter intruders and prevent a break-in.

3. Aside from the feature of generating alarm or help signals when intruders are detected, the SOS button 127 on the detection processor 10 can also be used to generate Morse code signals in the event of an earthquake or fire to increase the likelihood of help arriving. Thus, the invention has greater added value and is less likely to go unused.

4. The invention can also provide other functions, such as a lighting function in addition to the burglary prevention function. The photosensitive sensor unit 200 in the control circuit 20 of the detection processor 10 can automatically detect the brightness of light sources and send appropriate signals to the microprocessor unit 204, which sends signals to the lighting unit 208 to turn on or off the indicator light 15. Thus, in the event that users return home at night or a power failure occurs, the detection processor 10 can automatically generate light to indicate passageways or escape routes. In the event of a power failure, the flash button 122, the power failure lighting button 124 and the automatic lighting button 125 of the detection processor 10 can provide a lighting function.

In summary, a multiprocessor alarm system includes a plurality of detection processors 10. At least one detection processor 10 is located in each detection area T and each detection processor 10 is separately connected to a radio alarm device 30 and a radio assistance system using radio signals.

Claims (3)

1. Multi-processor alarm system, comprising a number of detection processors ( 10 ) with at least one detection processor ( 10 ) arranged in each detection area (T), each detection processor ( 10 ) being separately connected to a radio alarm device ( 30 ) and a radio assistance system ( 40 ) by means of radio signals, the detection processor ( 10 ) having a control circuit ( 20 ) which includes a first control unit ( 21 ) and a second control unit ( 22 );
wherein the first control unit ( 21 ) is characterized by: a storage unit ( 203 ) for storing a signal status;
a microprocessor unit ( 204 ) for processing and controlling signals and for comparing passwords entered with passwords pre-stored in the storage unit ( 203 ) to perform decoding;
an infrared light sensor unit ( 201 ) for emitting infrared light detection signals to the microprocessor unit ( 204 );
a radio transmitter ( 206 ) for transmitting signals from the microprocessor unit ( 204 );
a radio alarm device ( 30 ) for receiving signals from the radio transmitter unit ( 206 );
a radio assistance system ( 40 ) for receiving signals from the radio transmitter unit ( 206 );
a reserve power supply unit ( 210 ) to provide a reserve power supply for the control circuit and to charge via a charging circuit ( 20 ). 2. Multiprocessor alarm system according to claim 1, wherein the second control unit ( 22 ) is characterized by:
a lighting unit ( 208 ) for receiving signals from the microprocessor unit ( 204 ) to determine whether light sources should be turned on or off and to adjust the brightness of the light sources;
a photosensitive sensor unit ( 200 ) for sending light source detection signals to the microprocessor unit ( 204 ), which outputs signals to the lighting unit ( 208 );
an operating unit ( 202 ) for entering the passwords into the microprocessor unit 204 to release alarm conditions of the detection processor ( 10 );
a display unit ( 207 ) for displaying operating and status signals output from the microprocessor unit ( 204 );
an alarm unit ( 209 ) for receiving signals from the microprocessor unit ( 204 ) and for sending signals to an alarm indicator light ( 14 );
a loudspeaker unit ( 211 ) for receiving signals from the microprocessor unit ( 204 ) and for generating a sound to alert operators; and
an SOS unit ( 212 ) for receiving signals from an SOS button ( 127 ) and for sending signals to the microprocessor unit ( 204 ), which sends signals to the lighting unit ( 208 ), the loudspeaker unit ( 211 ) and the radio transmitter unit ( 206 ). 3. Multiprocessor alarm system according to claim 1 or 2, wherein the detection processor ( 10 ) comprises a housing having a surface characterized by:
a numeric input interface ( 11 ) to enter/reset the passwords;
a functional input interface ( 12 );
a display interface ( 13 );
an alarm indicator light ( 14 );
an indicator light ( 15 );
a detection device ( 16 ); and
a switch ( 17 );
wherein the detection device ( 16 ) includes an infrared light sensor ( 160 ) for automatically detecting the temperature of a human body or motion signals and a photosensitive sensor ( 161 ) for detecting a brightness of light sources;
wherein the functional input interface ( 12 ) includes a lighting button ( 120 ), a fluorescent button ( 121 ), a flash button ( 122 ), a time button ( 123 ), a power failure lighting button ( 124 ), an automatic lighting button ( 125 ), an automatic language selection button ( 126 ), and an SOS button ( 127 ).