DE3232924A1 - RADIATION DETECTOR ARRANGEMENT - Google Patents

Description

piPIi.-ING. H. MARSCH ιμΛϊιο, ι. 400öoüsseldorf ι.

TlTTT. τ tv: (-λ Ύζ «Τ» AT? T "Μ Ci HETHELSTBASSE 123

D11 L ·.-1 Λ Or. Iv. blAKlAtt post box 140268 DIP-K-PIIVS. I) R. AV. IL Ri) IIL phone (0211) 671034

RACAL SECURITY LIMITED
Lochend Industrial Estate
Newbridge, Midlothian EH28 8LP
Scotland / Great Britain

"Radiation detector arrangement"

The invention relates to a radiation detector device, such as one for detecting infrared radiation .

Infrared radiation detectors are known in the form of pyroelectric elements such as pyroelectric elements ceramic material, pyrolytic plastic film or crystalline material such as lithium tantalate or in the form of thermocouples or thermistors that respond to infrared radiation respond by generating an electrical output, such as an electrical voltage. Such Detectors are used for a variety of purposes, for example, they can be used in room protection for detection infrared radiation or changes in infrared radiation due to the intrusion of objects.

A problem with such infrared detectors is that they are sensitive to changes in environmental parameters, About ambient temperature, pressure, humidity or the like. Are, and that such changes in the environmental parameters cause may that the arrangement has a spurious outcome or a

causes spurious change in output.

It is known to use the detector devices in pairs, electrically connected in counter-circuit, to use, so that changes in the environmental parameters affect both detector devices essentially equally, the resulting outputs or Cancel output changes against each other. The detector devices remain able to perceive infrared radiation to be detected (for example resulting from

1.G unauthorized persons), since the order can be made in such a way that that this radiation does not fall on both detector devices at the same time, but first on the first and then on the second. However, a disadvantage of such an arrangement is that it has a relatively low sensitivity with regard to the infrared radiation to be detected, especially in view of the geometrical arrangement of the detectors. For example, if an unauthorized person gets into the If the field of view of both detectors is reached, the detector outputs will immediately cancel each other out and his Presence cannot be determined.

The present invention provides a radiation detector assembly according to claim 1, whereby said disadvantage is eliminated.

Further embodiments of the invention are to be taken from the following description and the subclaims.

The invention is explained in more detail below with reference to the exemplary embodiment shown schematically in the accompanying figure.

The illustrated infrared detector assembly 8 includes a sleeve 10 containing two substantially identical infrared detector devices 12 and 14 contains. Each detector device 12, 14 can have a surface area of approximately 2 χ 1 mm, the two devices for example are separated from each other by about 1 mm.

In this exemplary embodiment, the detector devices 12, 14 consist of pyroelectric ceramic material which is connected to two electrodes in each case. Each detector device 12, 14 responds to changes in the infrared radiation by generating an electrical output voltage of a predetermined polarity; when the change in radiation is over, the output voltage drops to zero.

Above the detector devices 12 and 14 is a window 16 arranged, for example made of germanium. or silicon and which is transparent to visible light, but permeable to infrared radiation. However is the part of the window 16 above the detector device 12 made opaque to infrared radiation with the aid of a suitable cover or coating 14, for example by means of a strip, which is arranged in good thermal contact with the window 16.

Each detector device 12, 14 can be viewed as a voltage source and the two detector devices lines 12 and 14 are electrical (by not shown Connecting lines) arranged in counter-circuit, so that the voltage outputs they generate in response to infrared radiation are opposite to one another are. The arrangement has output connections 20, 22.

in operation , the assembly 8 is positioned so that the window 16 is directed towards the area in which infrared radiation to be detected is expected. Any such infrared radiation passes the uncovered portion of the window 16 to fall on the detector device 14. The cover 18 prevents any such radiation from impinging on the detector assembly 12. Therefore, the detector assembly 14 will generate an electrical output signal in response to any change in the received radiation and, since the detector device 12 does not generate any

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speaking output is generated in the opposite direction, the result will be the generation of a signal to the Connections 20, 22 exist.

Any changes in the environmental parameters Such as the ambient temperature, pressure or humidity or the like. Which are of such a nature that they affect the output of the Detector devices 12, 14 affect, will affect each detector means 12 and 14 substantially equally. This is because the darkening, which is supplied by strip 18 only • prevents the transmission of infrared radiation to the detector device 12, but not the transmission of the detector device 12 prevents the effect of any environmental parameter that is otherwise caused by the Window 16 passed through. Therefore, changes in the environmental parameters that determine the output of the detector devices 12 and 14 affect each of these Facilities producing an electrical output of essentially the same value but opposite: Polarity so that the total output between terminals 20 and 22 does not change.

The result is that the arrangement according to FIG. 1 has a high sensitivity to infrared radiation, which can be ascertained, however, only a slight tendency to be influenced by changes in the environmental parameters owns. If only a single detector device were used, any changes would be made not corrected in the environmental parameters and appear immediately at the exit. On the other hand, it was found that Arrangements in which two detectors are present, which are connected electrically with opposite polarity, wherein both receive the infrared radiation to be detected, have only low sensitivity, as unavoidable in the Practice some of the radiation that falls on one of the detectors also falls on the other, despite the arrangements

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are arranged so that they operate so that the radiation to be detected only one of the two detectors at the same time impaired (first one detector, then the other, if the source of infrared generation passes the arrangement). Because of the opposing polarity in which the two detector devices are electrically are connected to each other, there is a reduction in the overall output.

It has been found that the advantages achieved with the illustrated arrangement are not achieved when the detector device 12 is shielded by between this and the window 16 or on the Surface of the detector device 12 attached a shield will. Such shielding reduces the effect of environmental changes on this detector, the take place outside the housing 10 in comparison with their effect on the other detector. Hence the '' Arrangement sensitive to environmental changes. The shield should therefore be arranged in such a way that it passes through the transmission of environmental changes that take place outside the housing 10 and in the vicinity thereof, not is significantly impaired. Such a shield can be attached to the inside of the window 16. Although the arrangement described using detector devices 12 and 14 in the form of pyroelectric ceramic elements have been described, it is not necessary that they have such a shape. Instead, other suitable elements can also be used which address an electrical output to generate the radiation to be detected. For example, pyroelectric plastic films or crystalline Forms such as lithium tantalate can be used. Instead, they can also be in the form of thermocouples or or thermistors are used. They can be electrically connected in counter-circuit in any way.

For example, they can have opposite entrances of a suitable amplifier or the output of one can be inverted and sent to the output of the to be added to others.

The shielding of the detector 12 can be accomplished in other ways. For example, the window 16 be redesigned yourself. For example, the window 16 could only be arranged above the detector device 14 as long as the material covering the detector means 12 is capable of external environmental changes ',. to the detector 12 in essentially the same way, ■ allow, in which they are "let through" to the detector Ϊ4> while, however, the radiation to be detected is not transmitted to the detector 12.

Claims (8)

DIPL.-ING. II. .KlARSCIUi ,.} ,, »· ,, · i (· · .. '/ iqoo düsseldoh DIP L. -1 N G. K. SPARING * imtiibmtrassb 123> · POST BOX 110208 ÜIPlÄ-niVS. I) R. Λ W II. ROHL telephone (oaii) 67io3i RACAL SECURITY LIMITED Lochend Industrial Estate Newbridge, Midlothian EH 28 8LP Scotland / Great Britain Claims 1.J radiation detector device comprising two radiation-sensitive devices, each of predetermined an electrical ^f "output polarity in response to deliver the reception of the radiation to be detected, the two radiation-responsive devices being electrically connected in counter-circuit, characterized in that the radiation-responsive devices (12, 14) are arranged such that one of them (14) freely receives the radiation to be detected IG can, while the other (12) is prevented from receiving this radiation, but both devices (12, 14) can respond freely to changes in other external environmental parameters, while the electrical connection of the devices (12, 14) is selected in such a way, that - _f 15, an electrical output is generated in response to receipt of the ■ q .festzustellenden radiation but substantially no electrical output in response to changes in the ambient parameters. <~ n * · * r t «6 · g t α # *" Ίι ο · 2. Arrangement according to claim 1, characterized in that each device (12, 14) is an infrared radiation detector device is. 3. Arrangement according to claim 2, characterized in that that each device (12,14) made of pyroelectric ceramic Material. 4. Arrangement according to claim 2, characterized in that each device (12, 14) consists of lithium tantalate. 5. Arrangement according to claim 2, characterized in -.10 that each device (12,14) consists of a pyroelectric ^: - ·. ^; 'ώ consists of plastic film. 6. Arrangement according to one of claims 1 to 5, characterized in that it comprises a cover (14) which is transparent to the radiation to be detected, wherein the two devices (12, 14) are arranged on one side of the cover (16), while a shield (18) for shielding the cover (16) on one of its two surfaces over a device (12), the other device (14) is arranged in a non-shielding manner, so that the device (12) does not receive any radiation to be detected can. 7. Arrangement with responsive to infrared radiation two pyroelectric devices responding to infrared radiation, electrically in opposition to one another are connected, a window made of a material that allows infrared radiation to pass through, over the two devices, characterized in that on the window (16) a screen (18) which is essentially for infrared radiation is impermeable, is arranged to prevent the transmission of infrared radiation to one of the devices (12), but not to block the other device (14), the reception of infrared radiation opening the window (16) by the other device (14) causes the arrangement (8) to produce a resulting electrical output, however changes in other external environmental parameters, • β «· which act on both devices (12, 14), resulting generate electrical outputs of the devices (12, 14), which are opposite and cancel each other out. 8. Arrangement according to claim 7, characterized in that that the infrared radiation permeable material is germanium or silicon.