WO2009091280A1 - Sensor for an alarm system - Google Patents

Abstract

The invention can be used in alarm systems. The technical result consists in the improved operational reliability and the ease of use. The sensor comprises a pulse shaping unit consisting of a microcontroller and a capacitance sensing element, wherein a comparator is a part of the microcontroller and operates as a multivibrator, the pulse shaping unit comprises at least two resistors which are used for setting the comparator to direct current and the connection point of which is connected to the noninverting input of the comparator, the output of which, being the output of the pulse shaping unit, is connected to the coating of the first capacitor via a time-setting resistor and to the noninverting input of the comparator by the inverting input of the comparator and via the positive feed back resistor, the second capacitor coating is connected to a neutral bus, wherein one of the coatings of the capacitors is formed by at least two directly not connected to each other conductor strips of a printed circuit on which the pulse shaping unit is mounted, and the second coating of the first and second capacitors are in the form of the metal elements of the protected object to which the printed circuit of the pulse shaping unit is secured by the lower side thereof, a photo transistor, for controlling the illumination of the lower side of the printed circuit and the body inside, is included into the pulse shaping unit circuit and is connected to the microcontroller.

Description

 ALARM SYSTEM SENSOR

Application area

The invention relates to alarm systems for theft or hacking of various, mainly electrical and electronic products, such as cell phones.

State of the art

A known alarm sensor with a piezoelectric signal transducer with time parameters varying depending on the mechanical effect, comprising a piezoelectric element electrically connected to a pulse generating unit, which has a feedback circuit including at least one feedback resistor, and the piezoelectric element is installed in this feedback circuit communication to create a self-oscillating circuit for changing the feedback parameters and time parameters of the output pulse sequence ka formation of pulses during mechanical action on the piezoelectric element (see patent RU Ne2168213, CL G08B 13/02, 11.27.1999).

The described sensor has a fairly high sensitivity even in the case of minimal mechanical impact on the guarded object. However, this sensor is only triggered by mechanical impact on the protected object, which narrows the scope of its use and does not allow it to be used in cases where it is possible to separate any part of the protected object on which the sensor is installed, for example, removal back cover of a cell phone, without mechanical impact on the sensor.

Closest to the invention in technical essence and the achieved result is an alarm system sensor containing a pulse shaping unit including a microcontroller and a capacitive sensitive element

(see GB patent JNi.2372363, CL G08B 13/14, 08.21.2002).

This sensor contains a capacitive-type sensitive element, which allows the sensor to give an alarm even in the absence of mechanical impact on the sensor. However, the implementation of the sensor in the form of two parallel insulated conductors passing through or around the protected product complicates the use of this sensor and requires the placement of a sensitive element in the protected product, which is not always possible.

Disclosure of invention

The problem to which the present invention is directed is the creation of an alarm system sensor that does not require the placement of other elements on the protected product or around it, and therefore does not require the opening of the protected product.

The technical result is to simplify the operation and increase the reliability of the sensor of the alarm system.

This problem is solved, and the technical result is achieved due to the fact that the sensor of the alarm system contains a pulse forming unit including a microcontroller and a capacitive sensitive element, while the comparator included in the microcontroller operates in a multivibrator mode, and the pulse forming unit includes at least two DC comparator resistors, the connection point of which is connected to the direct input of the comparator whose output, which is the output of the pulse forming unit, is connected through a time-setting resistor to the lining of the first capacitor, the inverse input of the comparator, and through p a positive feedback resistor with a direct input of the comparator, and the lining of the second capacitor is connected to the zero bus, moreover, at least two printed conductors of the printed circuit board, on which the pulse forming unit is assembled, form one of the capacitor plates, and the second lining the first and second capacitors are the metal elements of the protected object, to which is attached the bottom side, for example glued, the printed circuit board of the pulse forming unit, while the upper side on which the circuit elements forming unit pulse, last closed opaque body, and a part of the pulse generation unit circuitry includes a microcontroller coupled to the phototransistor to the illumination control circuit board and the lower side inside the housing.

During the development of the sensor, it was necessary to create a sensor as a finished product, which only needs to be fixed on the protected product. In this case, it was necessary, on the one hand, to simplify the design of the sensing element as much as possible sensor, and, on the other hand, to ensure the operation of the sensor, both when trying to damage the sensor itself, and in an attempt to separate the sensor from the protected product or to separate part of the product with the sensor from the protected product. The study revealed the possibility of using the printed conductors of the printed circuit board on which the sensor is assembled, as plates of “open” capacitors, which together with the metal parts of the protected object create a chain of two series-connected capacitors, with a change in the capacitance of which the generated multivibrator changes on the comparator built into the microcontroller, the frequency, as a result of which the sensor after software processing and analysis of the frequency change as a result of Changing the capacity gives an alarm. At the same time, when you try to open the sensor housing, the illumination changes in it, which causes the phototransistor to trigger, followed by the alarm being issued by the sensor.

Thus, the protected object becomes an integral part of the sensor of the alarm system and any attempt that changes the capacitive relationship originally established when the sensor was mounted on the protected object is fixed by the sensor.

Brief Description of the Drawings

Figure l presents a circuit diagram of a sensor of an alarm system. The best embodiment of the invention

The alarm system sensor contains a pulse shaping unit including a microcontroller 1, for example, PIC12F629, and a capacitive sensing element 2. The pulse shaping unit is made on a comparator, which is part of the microcontroller, and operating in the multivibrator mode. For the comparator to operate in multivibrator mode, the following external elements are used - two resistors 3 and 14 for installing a DC comparator, the connection point of which is connected to direct input 5 of the microcontroller 1 comparator, output 6 of which, which is the output of the pulse forming unit, is connected through a timing resistor 10 to the lining of the first capacitor 8 and to the inverse input of the comparator 9. The lining of the second capacitor 7 is connected to a common wire. Also, the output of the pulse forming unit 6 through the positive feedback resistor 4 is connected to the direct input 5 of the comparator of the microcontroller 1. The capacitor plates 7 and 8 form at least two printed circuit wires of the printed circuit board that are not directly connected to each other (not shown in the drawing), on which the pulse forming unit is assembled, and the second lining of the first and second capacitors 7 and 8 are the metal elements of the protected object 11, to which is attached the bottom side, for example, glued on both sides second tape, printed circuit board unit for generating pulses. On the upper side of the printed circuit board there are installed elements of the pulse forming unit circuit, which are closed by an opaque case (not shown), and the structure of the pulse forming unit includes a phototransistor 12, for example KP-3015PЗC connected to the microcontroller 1, to control the illumination of the lower side of the printed circuit board and inside the case. The sensor is connected to the alarm system through a group of contacts 13.

The alarm system sensor operates as follows.

The sensor is fixed, for example, glued, with the bottom of the printed circuit board to the protected object 11, which allows you to form the capacitance of the capacitors 7 and 8, which is stored in the memory of the programmable microcontroller 1, while these capacitors 7 and 8 together with the resistor 10 form a timing chain. At the same time, it is taken into account that the frequency generated by the multivibrator built into the microcontroller 1, in addition to the capacitance of capacitors 7 and 8, is affected by the comparator’s own capacitance, mounting capacitance, and printed circuit board capacitance, which are constant and can reach several tens of picofarads in total.

The sensor software monitors the frequency generated by the multivibrator. When the power is turned on, the initial frequency value is averaged and stored in the memory of microcontroller 1, and then continuously compared with the current read frequency.

When changing the distance between the sensor circuit board and the protected object 11 or its internal parts containing metal, the capacitance of the capacitors 7 and 8 changes, as a result of which the frequency generated by the multivibrator changes, assembled on a comparator, which is part of the microcontroller 1, where the changed frequency value is compared with the original value. Thus, when the value of the capacitive coupling of the sensor with the protected object is higher than the permissible value or when the value of the capacitive coupling changes sharply, for example, when the sensor is disconnected from the protected object, the changed capacitance value is transmitted to the multivibrator, which causes a sharp change in the frequency generated by the multivibrator and the microcontroller after software processing and Frequency change analysis generates an alarm.

At the same time, microcontroller 1 continuously averages the current frequency over the past few minutes and adjusts the value in the memory of microcontroller 1. This is necessary to compensate for the slow drift of the multivibrator frequency due to changes in temperature, humidity, etc. To eliminate the need to configure the sensors, an adaptive algorithm for calculating the sensitivity of the sensor is used. The larger the initial frequency deviation, i.e. the greater the capacitive coupling of the sensor with the object 11, the lower the sensitivity, but at the same time, the likelihood of a false response of the sensor. The lower the capacitive coupling, the greater the sensitivity, but also the higher the likelihood of a false positive. However, the maximum sensitivity value is limited. Inside the sensor case, the ambient light is constantly monitored by means of a phototransistor 12. When the sensor case is opened or the bottom side of the circuit board is exposed and, as a result, the light changes, the sensor is triggered and gives an alarm. Industrial applicability

The present invention can find application for the protection of various kinds of household goods and electronic equipment in stores and at various exhibitions with free access for visitors and buyers to the demonstrated models of equipment.

Claims

Claim

An alarm system sensor comprising a pulse shaping unit including a microcontroller and a capacitive sensing element, characterized in that the comparator included in the microcontroller operates in a multivibrator mode, and the pulse shaping unit includes at least two DC comparator installation resistors , the connection point of which is connected to the direct input of the comparator, the output of which, which is the output of the pulse forming unit, is connected to the circuit via a timing resistor the first capacitor, the inverse of the comparator and through the positive feedback resistor with the direct input of the comparator, and the lining of the second capacitor is connected to the zero bus, and one of the plates of the capacitors is formed by at least two printed circuit wires of the printed circuit board that are not connected to each other a pulse forming unit, and the second lining of the first and second capacitors are the metal elements of the protected object, to which is attached the bottom side, for example, glued, the printed circuit board of the pulse forming unit, while on the upper side on which the elements of the pulse forming unit circuit are installed, the latter is closed by an opaque body, and the pulse forming unit circuit includes a phototransistor connected to the microcontroller to control the illumination of the lower side of the printed circuit board and inside the case .