FR2534698A1 - Method of searching for and identifying a target placed beyond an opaque screen, and corresponding apparatus - Google Patents

Abstract

The apparatus for searching for and identifying a target placed beyond an opaque screen comprises: a transmitter 2 and a receiver 3 each provided with a very directional aerial 4, 5, which move in order to provide the scanning of a zone of the screen 16; a processing circuit 5 for detecting the absence of echo coming from the target 20, and a video display screen 8.

Description

Method for finding and identifying a target placed beyond an opaque screen, and corresponding apparatus,
The invention relates to a method of searching for and identifying a target placed beyond an opaque screen, and to an apparatus for implementing this method.
For the detection of prohibited objects in the luggage of airplane passengers, for example, it is known to use X-ray devices which reveal on a screen the shape of the objects contained in the luggage. These devices are very heavy and can only be fixed. In addition, if they make it possible to visually assess the shape of objects, especially metallic objects, they cannot give any indication of the chemical nature of the objects. Furthermore, the examination of baggage can only be carried out after presentation -by their holder.

 One of the aims of the invention is to propose an apparatus capable of detecting the presence, behind an opaque screen such as a suitcase wall or a partition for example, of a determined chemical body. According to another object of the invention, this device must ensure the representation of the outline of the target containing this chemical body.

The subject of the invention is a method of searching for and identifying a target placed beyond an opaque screen, using electromagnetic radiation, characterized in that
- an emitter and a receiver of electromagnetic radiation working in the band from 1 MHz to 100 Hz are used,
- an atom or a molecule having a resonance absorption frequency located in this band is defined among the characteristic components of the target sought;
- a screen area, surface and deep, is scanned, and
- during this scanning, the absence of echo corresponding to the absorption of the radiation by the target is detected
According to other features of the invention
- the result of the detection is displayed on a blank screen in order to show the shape of the target;
- the area is scanned by a microcomputer which controls the video screen.

The invention also relates to an apparatus for searching and identifying a target placed beyond an opaque screen, using electromagnetic radiation, characterized in that it comprises
- a transmitter and a receiver of electromagnetic radiation working in the band from 1 MHz to 100 GHz, each provided with a very directive aerial, the aerials being capable of coordinated movements to ensure scanning of an area of the opaque screen,
a circuit for processing the reception signal ensuring the detection of the absence of echo from the target, and
- a scanning circuit controlling a video screen.

According to other features of the invention;
- a microcomputer controls the movements of the aerials, and correspondingly the scanning circuit;
- the microcomputer controls the transmitter and the receiver to ensure scanning of the frequency range;
the transmitter and the receiver both simultaneously perform the transmission and reception functions by being calibrated on different frequencies so as to define an intermediate measurement frequency;
- to ensure area scanning, oscillating metal mirrors are mounted on the path of electromagnetic radiation from the transmitter, and are controlled by the microcomputer.

Other characteristics of the invention will emerge from the description which follows, made with reference to the accompanying drawing in which we can see
Figure 1 - a simplified symbolic diagram of an embodiment of a search and identification apparatus according to the invention;
Figure 2 a symbolic diagram explaining the operation of the device of Figure 1, the angles of incidence have been exaggeratedly enlarged for the sake of clarity.

 Referring to the drawing, it can be seen that the apparatus according to the invention essentially comprises a supply 1 for the transmitter circuit 2 and the receiver circuit 3 of the apparatus, the transmitter is coupled to an aerial 4, and the receiver to 'an aerial 5. These aerials are for example resonant cavities or horn-type antennas, due to the range of frequencies used which is between approximately 1 MHz and approximately 100 GHz.

 The receiver 3 is connected to a circuit 6 for processing the received signals which supplies a scanning circuit 7.

This scanning circuit 7 supplies a video screen 8 for immediate viewing of the result, and a recording memory 9, for example, for delayed viewing.

 Advantageously, the air lines 4 and 5 are mounted on a plate 10 and subjected to movements, coordinated by any appropriate means, to ensure a scanning of the zone to be interrogated-if necessary, We can for example provide a scanning in 20 lines approximately, each line being for example broken down into 20 points. In such a case, it is advantageous to simultaneously control the movements of the aerials 4, 5 and the image scanning circuit 7 by means of a microcomputer 11. The control of the movements is ensured by the line symbolized in 12 (the electrical and mechanical members imposing the movements on the aerials 4 and 5 being of the conventional type are not shown) and the control of the scanning circuit 7 is ensured by the line symbolized at 13.

 In the context of an application of the apparatus imposing a frequency variation of the transmitter 2 and the receiver 3, it is desirable to control the variations in working frequency, for example by scanning the frequency range, by means of from the same microcomputer 11, the command being transmitted by the line symbolized at 14.

 The operation of the device is analyzed in the following way (FIG. 2): the transmitter 2 generates an electromagnetic wave whose frequency lies in the range from 1 MHz to 100 GHz. This wave is radiated by the aerial 4 in a well-defined direction .15, It encounters a first dielectric obstacle 16 such as a wall for example, which it crosses, but part of the radiation emitted is reflected by the obstacle in the direction 17. This reflected radiation is picked up by the aerial 5 of the receiver and the reception circuit therefore perceives an echo.

 Similarly, the emitted radiation, which has crossed the first obstacle 16, encounters a second obstacle 18 and part of the radiation is reflected along 19 towards the aerial 5 of the receiver which also perceives an echo.

 After the second obstacle 18, the emitted radiation meets a target 20 which comprises atoms or molecules having a resonance absorption frequency, equal to the frequency of the emitted wave. In this case, there is no longer any signal echoed back to the receiver. The signal processing circuit 6 detects the absence of echo and controls the display of a point on the video screen 8.

 During the scanning of the observed area, it is thus possible to determine a representation of the target on the video screen 8.

 The apparatus according to the invention must fulfill a certain number of conditions. It must generate an electromagnetic wave capable of passing through a dielectric screen, while returning an echo to the receiver. This wave must have a high frequency to have an acceptable directionality, and this frequency must correspond to a characteristic frequency of absorption by resonance of a chemical body of the target sought.

 Beyond the screen, the range of the device is of the order of ten meters, and it emits electromagnetic power which is not harmful to the human body.

 The applications of this device are quite numerous and we can retain in particular those which are related to security.

 First of all, in the event of an earthquake, for example, one can search for the walled-in victims. The human body comprising a high proportion of water, the absorption frequency of which by resonance is .OCHz, one can calibrate the transmitter on this frequency and sees on the video screen 8 the silhouette of the victims, which allows their precise location before the start of the excavation work: this results in a saving of precious time. In the case where the zone is impregnated with water, we can take as absorption frequency by resonance that of potassium from red blood cells (3.75 MHz or 471 MHz), that of calcium from bones (5.4 MHz), or that of adrenaline (133.8 MHz). This is the case, for example, of searching for avalanche victims. In this way, it is possible to search for lost or missing persons without them having to wear transmitter equipment or a special signaling device.

 If one cannot use the frequency of absorption by resonance of a constituent of the human body, for reasons due to the environment for example, one can equip the people who will possibly have to be sought, with a tablet of a particular chemical body, placed for example in a garment or a shoe.

 By using the absorption frequency by resonance of a chemical body included in a person's identification badge, or in a brand worn by an item sold in stores, we can respectively ensure access control in certain premises, or an exit check after payment.

 The device can be used for non-destructive monitoring of a chemical process, remotely identifying a compound without the need to take a sample. We can thus control the disappearance of a compound, or its appearance, in a transformation process, in the food industry, for example.

 We can also continuously monitor, without sampling, a food preparation chain, whether or not conditioned, by seeking to detect the presence of toxic or dangerous products such as mercury (5.27 MHz and 14.3 MHz), lead (16.75 MHz), or arsenic (13.75 MHz) for example.

 In addition, one can seek to identify a chemical body contained in a suitcase or a bag, without the agreement of the traveler. In this case, it is preferable, if the body in question has not already been determined, to proceed by scanning the frequency range, so as to identify one or more bodies. We can thus detect the presence of explosives or narcotics, for example during a very discreet examination carried out using a portable device of small size.

 In the present description, the first surface encountered by the radiation emitted by the device is called a screen. Therefore if the obstacle in front of the device is a wall for example, the screen is constituted by the front face of this wall and the target can be located at any place beyond this face of the wall, including in the thickness of the wall.

 The screen can be constituted for example by the envelope of a tube in which the blood of a patient circulates during operation or treatment. The device can then provide medical surveillance.

 It should be noted that the transmitter and the receiver are both on the same side of the screen and in close proximity to each other, the device as a whole, portable.

 In order to facilitate the use of the device, the transmitter and the receiver can be operated at neighboring frequencies, for example 10 CHz and 10.4 GHz. Each of the two (transmitter and receiver) then performs the transmission function and the reception function in auto-mixing, using the intermediate frequency (0.4 GHz) resulting from the difference in frequencies. This arrangement is perfectly achievable thanks to the Gunn diodes for example.

 Note that examining an area of an opaque screen involves scanning the surface and in depth.

 Beyond the screen, in fact, it is necessary to ensure the examination of several parallel planes, located at increasingly greater distances from the device. For each of these depth plans, it is necessary to carry out a scan of the observed area. This scanning is done by lines, each line being assimilated to a series of points, for the representation on the video screen.

These different scans can be carried out by moving the aerials under the control of a microcomputer preferably.

They can also be secured using a set of two metal mirrors placed on the path of the emitted radiation.

One of these mirrors is mounted oscillating on a horizontal axis, it serves to ensure the scanning of the area in the vertical direction.

The other mirror is mounted oscillating on a vertical axis and it serves to ensure the scanning of the area in the horizontal direction.

 The reciprocal orientation of the two aerials ensures deep scanning beyond the screen.

 For monitoring a volume, for example of a room, from a closed niche not visible from the room itself, provision can be made to impose on the whole of the plate supporting the aerials movements - allowing the volume to be monitored to be scanned in several phases. As the power supply to the device can be autonomous, monitoring is protected from power outages or voluntary shutdowns.

 The apparatus according to the invention uses the absence of echo as a means of detecting the presence of a characteristic body. As a result, the aerials of the emitter and the receiver can be placed very close to each other, and both on the same side of the screen beyond which the wanted body is located. The device being as a whole, portable, this arrangement allows a very advantageous approach facility.

 -We may, however, have an interest in keeping the transmitter and the receiver away from each other, so as to give the device a wider surveillance field by increasing its range. The case arises in the case of an atmosphere analysis, in a large room or even outdoors.

 It should be noted that the apparatus according to the invention can give indications only with respect to a target placed behind a screen which provides an echo: if there is no echo, the apparatus cannot give any indication.

Claims (9)

 1. Method for finding and identifying a  target placed beyond an opaque screen, using electromagnetic radiation, characterized in that  - an emitter and a receiver of electromagnetic radiation working in the band of  1 MHz to 100GHz,  - one defines among the characteristic components  of the target sought an atom or a molecule having a  resonance absorption frequency located in this  bandaged,  - a screen area is scanned  opaque, surface and deep, and  - we detect during this scan the absence of echo  corresponding to the absorption of radiation by the target.  2. Method according to claim 1, characterized  in that we visualize on a video screen the result of  detection in order to show the shape of the target.  3. Method according to one set of claims 1 and 2, characterized in that one controls the scanning of the area by a microcomputer which controls the video screen.  4. Apparatus for searching and identifying a target placed beyond an opaque screen, using electromagnetic radiation, characterized in that it comprises:  - a transmitter (2) and a receiver (3) of electromagnetic radiation working in the band from 1 MHz to 100 GHz, each provided with a very directive aerial, the aerials (4, 5) being capable of coordinated movements to ensure a scanning an area of the opaque screen (16),  a circuit (6) for processing the reception signal ensuring the detection of the absence of echo from the target (20), and  - a scanning circuit (7) controlling a video screen (8).  5. Apparatus according to claim 4, characterized in that a microcomputer (11) controls the movements of the air (4, 5) and, correspondingly, the scanning circuit (7).  6, Device according to reyendication 5? characterizes in that the microcomputer (11> controls the transmitter (2) and the receiver (3) to ensure a scanning of the frequency range in order to identify an unknown body.  7. Apparatus according to claim 4, characterized in that the transmitter (2) and the receiver (3) both simultaneously perform the transmission and reception functions by being wedged on different frequencies so as to define an intermediate frequency of measurement.  8. Apparatus according to claim 4, characterized in that to ensure the area scanning, oscillating metal mirrors are mounted on the path of electromagnetic radiation from the transmitter (2), and are controlled by a micro-computer (11).  9. Apparatus according to claim 5, characterized in that the microcomputer controls the coordinated movements of the two aerials to ensure deep scanning.