FR2505098A1 - Wideband wave detector for RF signals - comprises flat oscillating panel containing metallic elements connected by diodes to cable - Google Patents

Abstract

A flat oscillating panel comprises metallic discs forming sub-assemblies which are resonant quarter wavelengths or a multiple quarter wave long. Each disc has a diameter of a quarter wavelength and is mounted at the same level on a rigid insulating support. The discs are insulated from each other. Auxiliary elements are located in front of or behind the sub assemblies and are insulated from them. They are aligned in the same direction as the sub assemblies. The auxiliary elements are connected to a coaxial cable through diodes. Similarly the sub-assembly elements are connected to the same cable through other diodes such that one element connects to the centre conductor while the other element of each sub assembly connects to ground. The diodes permit selection of the half-waves received by the elements for application to an amplifier. A metallic reflector is located behind the oscillating panel and a casing provides protection.

Description

 The present invention relates to the field of receiving radio waves, radar, or television, or the like, and relates to a sensor for such waves.

 Currently, sensors of this type, in particular existing television antennas, of the "yagi" type generally consist of a dipole or trombone tuned to the frequency to be picked up, and which is provided at its front part with one or more directors, and at its rear part of a reflector intended to improve its performance.

 These known antennas, however, have the drawback of being relatively bulky and of detracting from the aesthetics of the buildings on which they are installed.

In addition, their effectiveness on interference and echoes is reduced. Finally, the oscillations of a transmitter are captured individually by each element of the receiver. These elements being the seat of an alternating current, they must be separated from each other by a distance depending on the wavelength, in order to avoid excessive damping and, therefore, insignificant efficiency.

 The present invention aims to overcome these drawbacks.

 It has, in fact, for object a wave sensor characterized in that it is essentially constituted by an insulated flat oscillating panel, comprising several metallic elements connected by means of diodes to the coaxial cable, the diodes allowing a selection of the alternations received by the elements, possibly by a metal reflector which can be adjusted in distance from the insulated oscillating panel and disposed behind the latter, and, if necessary, by a protective casing for the assembly.

 According to a characteristic of the invention, the elements of the oscillating panel are in the form of two identical sub-assemblies connected, one at the center of the coaxial cable, and the other to the ground of said cable.

 According to another characteristic of the invention, the oscillating panel can be completed by two or more auxiliary elements, isolated and coupled to the front or to the rear of the oscillating panel, and connected to the coaxial cable, each by means of a diode, these diodes being arranged upside down.

 The invention will be better understood from the description below, which relates to a preferred embodiment, given by way of nonlimiting example, and explained with reference to the appended schematic drawing, the single figure of which is a view in perspective of a sensor according to the invention.

 The wave sensor represented in the appended drawing is constituted by a flat, metallic oscillating panel, formed by two subsets of elements 1, 1 'and 2, 2' connected by means of diodes 3 to 6 to a coaxial cable 7 , by a metal reflector 8 disposed behind the oscillating panel, and by a casing 9 for protecting the assembly in insulating material.

 Of course, it is also possible to produce the sensor without a reflector 8 and without a protective casing 9.

 Elements 1, 1 'of the first sub-assembly are connected to each other and to the center 10 of the coaxial target 7 with an arrangement of diodes 3 and 4 upside down, so that the alternations received on the two elements 1, 1' are separated. The same assembly is carried out with the elements 2, 2 ′ and the diodes 5 and 6, which are connected to the ground II of the cable 7. Thanks to this embodiment, the size of the sensor is notably reduced.

 The subsets 1, 1 'and 2, 2' shown are each in the form of metal discs, and resonating at most for about a quarter of a wavelength, or a multiple. Each of these disks has a diameter equivalent to about a quarter of a wavelength.

The elements 1, 1 'and 2, 2' thus obtained are isolated from each other, and mounted on the same level on any rigid insulating support.

 The metal reflector 8 which can advantageously be placed behind the oscillating panel while being isolated from the latter, is preferably adjustable in distance from the latter, for example by means of an adjustment screw passing through the bottom of the casing 9, so as to tune it as much as possible on the frequency of the program to be received. This reflector 8 improves the stability of the sensor and has a surface greater than that of the oscillating panel. This reflector could also be in the form of strips extending in the plane of the oscillating panel parallel to the elements 1, 2 and 1 ', 2'.

 In order to increase the efficiency of the sensor, it is planned, in accordance with another characteristic of the invention, to provide the latter, at the front or at the quarry with the sub-assemblies 1, 1 'and 2, 2' , two auxiliary elements 12 and 12 'connected to the coaxial cable 7, and coupled with the respective elements l, 1' and 2, 2 'by means of diodes 13 and 14 arranged upside down. These elements 12, 12 ′ have a variable surface according to their position, this surface being greater than that of a subassembly when they are placed behind the latter, or less when they are placed in front. These elements 12, 12 'are also isolated from elements 1, 1, 2, 2' and are aligned in the direction of elements I, 1 'and 2, 2'.

 Thanks to the invention, it is possible to produce a wave sensor having a very high sensitivity, with very wide bandwidth, and by which the received signals will be very pure t minimized interference and echoes, sor. e that it could be coupled to an amplifier allowing to receive more distant emissions. In addition, the size of a sensor tcl is very small because the flat elements and, optionally, 1 reflector can, ie if necessary, be housed in a housing of small dimensions.

 Of course, the invention is not limited to the embodiment described and repent in the accompanying drawing. Modifications remain possible, in particular from the point of view of the constitution of the various elements, or by substitution of technical equivalents, without thereby departing from the scope of protection of the invention.

Claims (6)

 1. Wave sensor characterized in that it is essentially constituted by an insulated flat oscillating panel, comprising several metallic elements (1, 1 ', 2, 2') connected by means of diodes (3 to 6) to the coaxial cable (7), the diodes allowing a selection of the alternations received by the elements, possibly by a metal reflector (8) which can be adjusted in distance from the insulated oscillating panel and disposed behind the latter, and, if necessary, by a casing (9) for protecting the assembly in insulating material.  2. Sensor according to claim 1, characterized in that the elements of the oscillating panel are in the form of two subassemblies (1, 1t and 2, 2 ') preferably identical connected, one in the center (10) of the coaxial cable (7), and the other to ground (ll) of said cable (7).  3. Sensor according to any one of claims 1 and 2, characterized in that the oscillating panel is completed by two or more auxiliary elements (12, 12 ') isolated and coupled to the front or to the rear of the panel oscillating, and can be connected to the coaxial cable (7), each by means of a diode (13, 14), these diodes being arranged upside down.  4. Sensor according to any one of claims 1 to 3, characterized in that the elements (l, 1 ') of the first sub-assembly are interconnected and at the center (10) of the coaxial cable (7) with a arrangement of the diodes (3 and 4) upside down, and the elements (2, 2 ') of the second sub-assembly are also connected to each other and to the ground (11) of the coaxial cable (7) with an arrangement of the diodes (5 and 6) head-to-tail  5. Sensor according to claim 3, characterized in that the auxiliary elements (12, 12 ') have a variable surface as a function of their position relative to the oscillating panel, this surface being greater than that of a subassembly when 'they are placed behind the latter, and lower when placed in front, and, they are aligned in the direction of the respective sub-assemblies.  6. Sensor according to any one of claims 1 to 5, characterized in that the elements (1, 1 ', 2, 2r) of the subassemblies of the oscillating panel have a length approximately equivalent to that of a quarter of wavelength or multiple.