DE2626306B2 - Triple reflector with built-in light sensor - Google Patents

Description

The invention relates to a triple reflector for evaluating the values falling into it and at it <· 5 reflected light beam contained information.

The use of a triple reflector, e.g. B. in the form of a triple prism or a triple mirror for Reflection of optical signals, especially laser signals, in a direction opposite to the direction of incidence is generally known (ViIbig, "Textbook of High Frequency Technology", 5th ed. 1960, p. 747; Proceedings of IEEE, July 1965, p. 734). Because of Of these properties of triple reflectors, they find, inter alia. when using for distance measurement.

However, the use of a reflector in the form of a surface-of-revolution reflector in FIG an optical receiving system known with a light sensor connected downstream of the reflector. It is not possible to reflect back part of the received light beam by reflection in a direction opposite to the direction of incidence (CH-PS 4 68 615).

Also when setting up and maintaining laser communication links, etc., an alignment of the Laser beam on the receiving station and readjusting this alignment required, with the help echo signals generated by a triple mirror at the receiving station are used. In such laser communication lines, the detectors are the modulated laser signals separately from the triple prism used to maintain alignment attached to the receiving device.

The invention is based on the object of creating a triple reflector that is not only used for reflection, but is also suitable for receiving light signals.

According to the invention, this object is achieved by that behind a surface which is plane-parallel to the light entry surface of the triple reflector or behind one of its Reflecting surfaces a light sensor is arranged

For such a triple reflector it is provided that the light sensor is for one of a laser transmitter originating light beam is a laser receiving diode

With such a triple reflector designed according to the features of the invention can be omitted the core of the laser beam directed onto the triple reflector, d. H. at the point of highest energy content, the modulated laser signal itself for the purpose of Hide message extraction. With the help of the lens system that may be provided for focusing the masked-out beam, this is turned on adapted to the size of the photoactive layer of the light sensor or the laser receiving diode

According to a special embodiment of the invention it is provided that the tip of the triple prism or triple mirror is cut plane-parallel to the entrance surface, and that the laser receiving diode im Area of the cut tip is arranged. This can be used in a particularly advantageous manner Scan the core beam of a laser beam, which makes the signal-to-noise ratio particularly special is to be designed inexpensively.

The lens system provided for focusing the masked beam of rays can also be designed in such a way that the rear exit surface of the triple mirror is ground lens-shaped, that the laser receiving diode with its effective area is arranged in the focal point of the lens system or in the vicinity of the focal point. It However, it is also provided that one of the reflective surfaces of the cube-corner mirror is provided with an exit window is provided, behind which the laser receiving diode is arranged. In this embodiment of the invention because of the deflection of the beam at the mirror surfaces, the modulated one can even then be modulated

Laser signal received when a conventional photodiode is only very weak when the incidence of light is at an angle or would not be illuminated at all.

Another embodiment of the invention also provides that between the light sensor and the exit surface, or the exit window a filter and possibly a lens system for focusing the masked out Beam is provided on the surface of the photoactive layer of the light sensor

In order to weather the portion of the rays falling on the light sensor when the bundle of rays is incident at an angle to enlarge, it is also provided that the lens system to enlarge the reception angle in a Immersion liquid is embedded in this immersion liquid can also be between the rear exit surface of the lens-shaped bevel and the be introduced active surface of the light sensor. With the help of such an immersion liquid, the Refractive index changed and thus an increase in the numerical aperture can be achieved.

With the measures of the invention is in advantageously allows a reduction in the dimensions of the device on the receiving side, since on a no separate detector housing and a closed, uniform design for the optical Input stage in connection with the triple prism for generating echo signals can be achieved without that through the exit window on the cube-corner mirror, a loss of light which has a detrimental effect in practice can be determined by the invention, a very small design and optimal utilization of the incident light in the area of the nuclear beam.

According to the invention it is also provided that the triple reflector for a communication system A signal processing stage is connected downstream of the triple reflector at the receiving end and a modulator through which the reflected light beam with a corresponding one supplied by a signal processing stage on the transmission side Modulation signal is pulse modulated.

The advantages and features of the invention also emerge from the following description of FIG Embodiments in connection with the claims and the drawing. It shows

F i g. I a perspective view of a corner cube with a detector diode arranged in the prismatic mirror tip;

F i g. 2 shows a section through a cube-corner mirror with one arranged behind a reflective surface Detector diode;

F i g. 3 shows a section through the schematic structure of a detector diode with an immersion liquid embedded lens system;

F i g. 3a shows another embodiment of the structure of a Detector diode;

4 shows a schematic representation of a laser communication system using a triple mirror according to the invention.

In Fig. 1 is a cube-corner mirror in schematic form Representation shown from the rear, in which each incident light beam due to the indicated beam deflection is reflected back into its starting point. The tip of the cube corner 10 is along a Plane-parallel to the entry surface plane 11 is cut off. On the $ e level is a laser receiving diode 12, which is also referred to as the detector diode below, is put on that the through The beam passing through the plane 11 strikes the photoactive layer of the detector diode

If you run out of rlavon that the laser transmitter very much is precisely aligned with the cube-corner mirror and the core of the directed laser beam is aimed at the Detector diode arranged at the tip of a triple mirror impinges, despite the small amount of the Detector diode detected laser beam cross-section derive a sufficiently large signal to ensure a safe Communication link between the laser transmitter and the laser receiver assigned to the triple mirror to ensure.

However, also in the event that the detector diode 12 as in FIG. 2 is not arranged in the cube corner, but behind an exit window on a rear reflective surface of the corner cube, perfect reception of the laser signal can be achieved due to the deflection of the laser beam 18 at the rear reflective surfaces of the corner cube. This deflection at the reflecting surfaces even results in a certain compensation effect when Of - the triple mirror sees something under angled light is illuminated more. As can be seen from the schematic representation according to FIG. 2, however, the deflected light beam hits a photoactive layer at a more favorable angle, so that it is still sufficiently illuminated.

In the event that further compensation for inclined incidence of light is desirable, between the exit window and the photoactive layer 16 of the detector diode 12, a lens system 14 is arranged with which the light rays are focused on the photoactive layer. Included can by inserting immersion liquid 15 between the exit window and the photoactive layer 16 the refractive index can be changed in such a way that an increase in the numerical aperture is effected. Such a configuration is shown in FIG. 3 for a planar hollow exit surface and in FIG. 3a for a Shown or alis-ground rear exit surface.

In Fig. The use of a cube-corner mirror with a built-in detector diode for a communication system is schematically indicated in FIG. The photoactive layer 16 generates an electrical signal which is amplified in a subsequent amplifier 20 and a discriminator 21 is fed to the "u ^c the laser beam to obtain 18 pulse-like modulated information content. In a subsequent decoder 22, the signal obtained by demodulation is decoded and either brought to the reproduction in a signal reproduction stage 23 or fed to a reaction stage 24 which triggers any desired secondary functions when an output signal occurs at an output terminal 25. The signal reproduction stage can contain reproduction devices for acoustic and / or optical reproduction.

A microphone 26 is used to transmit messages in the opposite direction Modulation signal generated in a modulation stage 27, which after amplification in an amplifier 28

a modulator 29 is supplied, which corresponds to the laser beam 30 reflected by the cube-corner mirror the modulation signal is pulse-modulated. The reflected laser beam 30 is also only half-width indicated

The modulator 29 is freely permeable to the laser beam 18 in the receiving mode, i. H. the laser beam does not experience any significant weakening. In the transmission mode, the reflected laser beam 30 is conventional Modulated way

With such a structure of the laser communication system can on the receiving side on a separate laser transmitter can be dispensed with, since the desired information content is based on the Triple mirror reflected laser beam aufmodulicri can be.

The measures of the invention make it possible to reduce the size of the devices on the receiving end with respect to

"> Achieve their design and size, while at the same time the incident laser beam can be optimally exploited by the scanning being carried out essentially in the core of the signal lobe without causing any significant loss in terms of the reflected light

occurs in abundance. By providing a filter: between the corner cube, z. B. on level 11. unc of the detector diode 12 can have a spectral range which is particularly favorable for reception by the detector diode be filtered out.

1 sheet of drawings

Claims (9)

Patent claims: 1. Triple reflector for evaluating the light beam that falls into it and is reflected on it information contained, characterized in that behind a surface which is plane-parallel to the light entry surface of the triple reflector (10) (11) or a light sensor is arranged behind one of its reflective surfaces 2. triple reflector according to claim 1, characterized characterized in that the light sensor for a light beam originating from a laser transmitter Laser receiving diode is 3. triple reflector according to claims 1 and 2, characterized in that the triple mirror tip is cut flat parallel to the entrance surface, and that the laser receiving diode in the area of the truncated corner cube is arranged 4. triple reflector according to claims 1 and 2, characterized in that the rear The exit surface of the triple mirror (10) is ground to the shape of a lens and that the laser receiving diode with their effective area in the focal point of the lens system or in the vicinity of the focal point is arranged 5. triple reflector according to claims 1 and 2, characterized in that one of the reflective surfaces of the triple mirror with an exit window is provided behind which the laser receiving diode is arranged 6. triple reflector according to one of claims 3 to 5, characterized geke: nzeich that between the light sensor and the exit surface, or «Ms exit window a filter and, if necessary, a lens system (14) for focusing the output beam group J5 dels is provided on the surface of the photoactive layer (16) of the light sensor. 7. Triple reflector according to one or more of the Claims 1 to 6, characterized in that the lens system for increasing the reception win- »0 kels is embedded in an immersion liquid (15). 8. triple reflector according to one or more of claims 1 to 6, characterized in that between the rear exit surface of the lens-shaped bevel and the active surface of the An immersion liquid is introduced into the light sensor. 9. triple reflector according to one of claims 1 to 8, characterized in that the triple reflector:> o is used in a communication system in which the triple reflector (11,12) A signal processing stage (20, 21, 22, 23) is connected downstream on the receiving side and before its on the transmitting side A modulator (29) is connected upstream of the light entry surface κ is, and that the reflecting light beam (30) with a corresponding one of a transmitting side Sifinalververarbeitungstufe (26, 27, 28) supplied modulation signal can be modulated. 60