DE19532679A1 - Design for optical (IR) system - Google Patents

Abstract

The optical system has an optical section (40) with at least one optical body (31,30) is used for directionality and steering of the optical radiation (13,16). The optical body is associated with either the transmitter (11) or receiver (14) and the fresnel lenses are symmetrically constructed. The optical head holds an unstructured surface area side (35) which has a symmetrical indentation (33) with a similar side to a have a structured surface area side (32). The indentation supplies the structured surface area side of the optical head and is for the receiver/transmitter to detect the optical radiation facing the receiver/transmitter. The optical bodies are preferably Fresnel lenses and are made from plexiglass, with a diameter of 20mm and a thickness of 2mm.

Description

The optical unit of a variety of optical systems - for example (IR) remote control systems, optical signal transmission systems or optical Anti-theft systems - consists of a transmitter unit with or several transmitting elements, one receiving unit with one or more emp catching elements and an optical path, via the transmitter unit and emp catcher are coupled together. The one sent by the sending unit optical radiation is emitted by the Emp after passing through the optical path Detection unit detected and this reception signal in an evaluation unit of the optical system processed. By changing the system properties ten - for example as a result of a variation in the emitted optical radiation by transmission of differently coded signals or by changes in the optical path - the received signal is influenced and this from the off unit of value evaluated.

To influence the optical properties of the optical unit - for example as to increase or homogenize the sensitivity of reception unit - an optical body can be arranged in the optical path.

From the EP 441 713 discloses this optical body as a toric, aspherical exterior Sheathing lens form, the multiple receiving elements (photocells) Surrounds the receiving unit. Furthermore, in DE 44 07 911 one in the optical Route between the sending unit and receiving unit arranged katadioptri optical body for deflecting and bundling the emit from the transmitter unit be radiation on the (only) receiving element of the receiving unit wrote.

It is the object of the invention to provide an optical system which is advantageous te properties - in particular a simple and inexpensive Structure and a favorable distribution of optical radiation.  

This object is achieved by the features in the characteristic of Claim 1 solved.

Advantageous developments of the invention result from the subclaims chen.

To improve the optical properties of the optical system is in the optical path between the transmitting unit and receiving unit at least one in the kind of a Fresnel lens optic body with a structured upper surface side and an unstructured surface side provided; the (the) Op The optical body is (are) assigned to either the transmitting unit or the receiving unit net, the optical body in each case in the immediate vicinity of the transmitter unit or arranged the receiving unit and its structured surface side of the Sen unit or facing the receiving unit. The structure of the structured The surface side of the optical body (s) is designed as a groove structure, wherein similar symmetrical depressions with a certain angle of inclination (Flank angle) are introduced into one of the surface sides of the optic body; this defines lens areas with the same prism angle, which act as a beam splitter and which the optical radiation into certain angles distract rich, with both flanks of the recess due to their symmetry Deflect the radiation. The optic bodies each have a symme trical form, whereby the selected symmetry (for example point symmetry, Axis symmetry) of the desired or given optical properties create and of the design of the transmitting elements or receiving elements depends on the assigned sending unit or receiving unit (with similar Sending units or receiving units are preferably of the same shape Exercise and thus the same symmetry of the optic body selected). For example the optical body is designed as a circular disk or as a cuboid; the order the groove structure on the structured surface side of the optic body can for example rotationally symmetrical in the form of concentric circles or in the form parallel lines can be formed. The groove structure becomes a saving of size and weight preferably applied so that as many as possible Grooves are formed on the thinnest optic body possible.

The optic body is made of a transparent material with egg refractive index that differs from that of the optical path (at for example made of plastic). The (the) optic body is (are) used for deflection the beam direction, the structured surface side being optically refractive  Surface either to deflect the optical emitted by the transmitter Radiation in a certain spatial direction or to distract from the Emp optical unit to be detected from a specific space direction acts on the receiving unit. Because every lens area due to symmetrical arrangement of the depressions of the groove structure equal deflections properties, any number of transmission elements or Receiving elements of the transmitting unit or receiving unit behind the arranged optic body can be arranged without who exactly positioned have to.

The optical unit of the optical system combines several advantages:

• - It has a simple and therefore inexpensive structure: number and Positioning of the sending elements and receiving elements are arbitrary selectable, it is a compact design of the optic body (small thickness) and thus given a very small size, the optic body can simple way (for example by injection molding) and therefore inexpensive are manufactured,
• - The optical properties can be improved: the deflection of the Optical radiation is easily produced by refraction ligt, by variation of the prism angle the main reception direction can be varied, with a small volume z. B. a cone jacket shaped area are illuminated,
• - Any optical radiation can be used - in particular re visible light or IR radiation.

The invention is further based on an illustrated in the drawing leadership example described - the optical unit one as an optical thief steel security system (alarm system) used in motor vehicles and with IR radiation working optical system.

Here, the Fig 1 2 in plan view. 4 shows the side view of the motor vehicle, the Fig. The monitoring area of the alarm system, Fig. 3, the optical unit and the Fig. The optic body in plan view.

In Fig. 1 is a side view of the interior 20 of the motor vehicle 1 with the side windows 21 , 22 , the front seats 23 , 24 and the rear seats 25 and the centrally located in the motor vehicle 1 (for example on the headliner) opti cal unit 10 is shown; E.g. is assigned to both the transmitting unit of the optical unit 10 and the receiving unit of the optical unit 10 , an optical body arranged in the immediate vicinity of the transmitting unit or the receiving unit. The monitoring area of the alarm system is determined by suitable deflection of the radiation 13 emitted by the transmitting unit of the optical unit 10 or by the receiving unit of the optical unit 10 after passing through the optical path 40 (reflected on the interior of the motor vehicle 1 ) detected radiation 16 . The directional characteristic of the optical radiation 13 , 16 , for example in the form of IR radiation (of, for example, 950 nm wavelength) is predetermined by a corresponding configuration of the optical unit 10 .

Fig. 2 shows the interior 20 of the motor vehicle 1, the illumination type region of the light emitted by the transmitting unit of the optical unit 10 radiation 13, which is roughly the Überwachungsbe defined by the optical unit 10 of the interior 20 reaching the alarm corresponding to (of the motor vehicle 1 is in a plan view with the front seats 23 , 24 and the rear seats 25 is shown schematically). As can be seen from the surveillance area of the alarm system, effective protection against intrusions into the interior 20 of the motor vehicle 1 through the side window panes 21 , 22 or against theft of objects from the interior 20 of the motor vehicle 1 through the side window panes 21 , 22 is given .

According to FIG. 3, the optical unit 10 of the alarm system has an IR transmission unit 11 with the transmission elements 12 (IR transmission diodes) and an IR reception unit 14 with the reception elements 15 (IR reception diodes). In the optical path 40's , two optics bodies 30 , 31 designed as a type of Fresnel lens are arranged directly in front of the transmitter unit 11 and the receiver unit 14 . The two optics bodies 30 , 31 of the same type are designed as circular disks, a surface side 35 of the optics bodies 30 , 31 being unstructured and a rotationally symmetrical groove structure made of similar depressions 33 being introduced into a surface side 32 of the optics bodies 30 , 31 ; the optical unit 30 assigned to the transmitting unit 11 is used to bundle the IR radiation 13 emitted by the transmitting elements 12 , the optical unit 31 assigned to the receiving unit 14 is used to deflect or bundle the IR radiation 16 coupled into the receiving elements 15 of the receiving unit 14 . The optic bodies 30 , 31 consist for example of plexiglass and have a diameter of 20 mm and a thickness of 2 mm. The depressions 33 in the surface side 32 of the optics body 30 , 31 facing the transmitter unit 11 or the receiver unit 14 are, for example, notch-shaped with similar flanks 34 and have a depth of 0.5 mm and a width of 1 mm, so that they act as beam splitters prismatic sections with a prism angle or flank angle of 45 ° are formed.

According to FIG. 4, the transmitter unit 11 has, for example, four IR transmitter diodes 12 , each of which has a transmitter diode 12 associated with a quarter circle sector of the optical body 30 provided with a groove structure having depressions 33 in the form of concentric circles; the equidistantly distributed transmission diodes 12 of the transmission unit 11 are arranged at a distance of, for example, 2 mm from the optical body 30 . The receiving unit 14 not shown in FIG. 4 has, for example, the same structure as the transmitting unit 11 , ie there are four IR receiving diodes 15 equidistantly distributed at a distance of 2 mm from the optical body 31 .

Claims (7)

1. Optical system with an optical unit ( 10 ) from:

• a) a transmission unit ( 11 ) with at least one transmission element ( 12 ) for emitting optical radiation ( 13 ),
• b) a receiving unit ( 14 ) with at least one receiving element ( 15 ) for the detection of optical radiation ( 16 ),
• c) an optical path ( 40 ) for transmitting the optical radiation ( 13 , 16 ) between the transmitting unit ( 11 ) and the receiving unit ( 14 ),

characterized by :

• d) at least one optical body ( 30 , 31 ) for focusing and deflecting the optical radiation ( 13 , 16 ) is arranged in the optical path ( 40 ), the optical body ( 30 , 31 ) either of the transmitting unit ( 11 ) or is (are) assigned to the receiving unit ( 14 ),
• e) the optical bodies ( 30 , 31 ) designed symmetrically as a type of Fresnel lens have an unstructured surface side ( 35 ) and a structured surface side ( 32 ) with symmetrical depressions ( 33 ) with similar flanks ( 34 ),
• f) the provided with recesses ( 33 ) structured surface side ( 32 ) of the optical body ( 30 , 31 ) is either as the entry surface of the emitting unit ( 11 ) emitted optical radiation ( 13 ) of the transmitting unit ( 11 ) or as the exit surface of the Receiving unit ( 14 ) to detect optical radiation ( 16 ) facing the receiving unit ( 14 ).

2. Optical system according to claim 1, characterized in that the Optikkör by ( 30 , 31 ) are designed as circular disks. 3. Optical system according to claim 1 or 2, characterized in that on the structured surface side ( 32 ) of the optical body ( 30 , 31 ), the depressions ( 33 ) are arranged in the form of concentric circles. 4. Optical system according to one of claims 1 to 3, characterized in that on the structured surface side ( 32 ) of the optical body ( 30 , 31 ) arranged recesses ( 33 ) are notch-shaped with similar symmetrical flanges ( 34 ). 5. Optical system according to claim 4, characterized in that the inclination angle of the flanks ( 34 ) of the recesses ( 33 ) is 45 °. 6. Optical system according to one of claims 1 to 5, characterized in that the transmitting unit ( 11 ) or the receiving unit ( 14 ) has a plurality of equidistantly arranged transmission elements ( 12 ) or receiving elements ( 15 ).