Abstract:
In order to improve target illumination, a light source ( 2 ) of an emitter, which has a laser diode ( 3 ) configured as an edge emitter with a wavelength of 1,550 nm, has beam forming optics ( 4 ) mounted downstream in relation thereto, which comprise a cylindrical lens ( 7 ) and a first deflection element ( 8 ) with three fields having different diffraction structures. Said deflection element are located next to one another and crosswise in relation to the first fields and which also have different diffraction structures. Said deflection element directs the partial beams to the aperture of a collimator ( 1 ) in such a way that the partial beams substantially fill said aperture. The first deflection element ( 8 ) and a mount ( 6 ) for the cylindrical lens ( 7 ) are integral and, alike the second deflection element ( 10 ), are made of plastic. Both parts are glued to opposite sides of the frontal areas of a block ( 5 ) made of glass.

Description:
TECHNICAL FIELD  
         [0001]    The invention relates to an optical telemeter such as employed for instance in the surveying of plots of land and buildings.  
         PRIOR ART  
         [0002]    Optical telemeters of this kind have been known for some time already. The laser diodes used as light sources have the disadvantage, however, that the light beam exiting at the emission edge has a very long and narrow cross section. This leads to poor target illumination, since only part of the light beam strikes the target thus detracting from the range and from measuring accuracy. Moreover, reflection of parts of the beam missing the target at other objects, which for instance are more distant, may acutely disturb the measurements.  
         DESCRIPTION OF THE INVENTION  
         [0003]    The invention is based on the task to specify an optical telemeter of the above kind providing a better target illumination than known telemeters of this kind.  
           [0004]    The advantages attained by the invention chiefly reside in a decisive improvement of range, i.e., the maximum distance that can be measured or, for a given range, in an increased measuring accuracy. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0005]    In the following, the invention is described in greater detail with the aid of figures representing merely one embodiment.  
         [0006]    [0006]FIG. 1 a  schematically shows a lateral view of an emitter of a telemeter according to the invention.  
         [0007]    [0007]FIG. 1 b  schematically shows a top view of the emitter according to FIG. 1 a,    
         [0008]    [0008]FIG. 3 shows a top view in beam direction of a first deflection element of the emitter according to FIGS. 1 a, b,    
         [0009]    [0009]FIG. 4 shows a top view counter to the beam direction of a second deflection element of the emitter according to FIGS. 1 a, b,  and  
         [0010]    [0010]FIG. 5 shows the target illumination attained by the emitter according to FIGS. 1 a, b.   
     
    
     WAYS TO PRACTICE THE INVENTION  
       [0011]    An optical telemeter according to the invention comprises an emitter as well as a receiver that, in known manner, can for instance be built up with optics and avalanche photodiodes, and further comprises an electronic control and evaluating unit also of known design controlling the emission of light pulses by the emitter and evaluating the output signal of the receiver. The distance can be measured by transit-time determination or by the phase-matching technique.  
         [0012]    The emitter has a collimator  1  and a light source  2  put in front of it which is composed of a laser diode  3  and beam forming optics  4 . The laser diode  3  is an edge emitter emitting electromagnetic waves in the infrared, preferably at a wavelength between 850 nm and 980 nm or a wavelength λ=1,550 nm. The emission edge has a length between 30 μm and 800 μm while its width is between 1 μm and 3 μm. The emission edge may be interrupted in its longitudinal direction. For instance, instead of one laser diode  3  a linear array of laser diodes having edge lengths of for instance 50 μm and distances between successive edges of 100 μm could be provided. The numerical aperture corresponding to the sine of half the angular aperture has a value of 0.1 parallel to the emission edge and of 0.6 to 0.7 transverse to this edge. The product of these two quantities, known as space bandwidth product (SBP), in a direction transverse to the emission edge approximately corresponds to the wavelength, and thus is practically monomodal (transverse mode of 0), i.e., it is close to a fundamental limiting value that cannot be exceeded, while parallel to the emission edge it is larger than this limiting value by a factor of 10 to 100. Even in this direction the SBP cannot be altered by conventional refracting elements such as lenses, but with the aid of elements based on diffraction or refraction of light, it can be lowered very close to the emission edge by rearrangement in a direction parallel to the emission edge but instead be enhanced in a direction transverse to this edge, and thus the light beam can be more strongly collimated.  
         [0013]    This is the purpose of the beam forming optics  4  comprising a parallelepipedal block  5  consisting of a transparent material, preferably glass, with a first front face turned toward the laser diode  3  and an opposite second front face turned toward the collimator  1 . The first front face supports a mount  6  of plastic holding a cylindrical lens  7  at its terminal zones. The cylindrical lens  7  has a circular cross section, its diameter is about 60 μm. It is oriented parallel to the emission edge of laser diode  3  and spaced apart from this diode by about 10 μm. The beam exiting from the emission edge which for laser diodes of the kind employed has a large transverse radiation angle of about 80° is made parallel by it. The diameter of the cylindrical lens and its distance from the emission edge may also be much larger than the given values, but for small values, particularly for values of at most 65 μm and at most 15 μm, respectively, the overlap of the fractions coherently radiated from successive regions of the edge is very small so that the losses caused by this overlap are also kept low.  
         [0014]    Downstream of the cylindrical lens  7  a first deflection element  8  is arranged which is integral with the mount  6  and has a structured surface that is essentially plane and parallel to the first front face of block  5 . Parallel to the emission edge it is divided into three successive fields  9   a, b, c  having different stepped diffraction structures. The second, opposite front face of block  5  supports a second deflection element  10  consisting of plastic and comprising a structured surface essentially plane and parallel to the second front face that is divided into three successive fields  11   a, b, c  transverse to the emission edge also having different stepped diffraction structures.  
         [0015]    The upper field  9   a  of the first deflection element  8  has a structure such that it deflects the partial beam exiting from an upper segment of the emission edge and striking it to the left-hand field  11   a  (looking in beam direction) of the second deflection element  10  where the beam is insignificantly deflected so that it will strike the collimator  1  and approximately fill the left-hand third of the collimator&#39;s aperture. In exactly corresponding manner, the lower field  9   c  of the first deflection element  8  deflects the partial beam exiting from a lower segment of the emission edge and striking it, to the right-hand field  11   c  (looking in beam direction) of the second deflection element  10 , where this beam, too, is deflected precisely in the corresponding way and then fills approximately the right-hand third of the aperture of collimator  1 . The central third of the collimator is filled by the partial beam exiting from a slightly shorter central segment of the emission edge and passing without deflection through the unstructured central fields  9   b  and  11   b  of the first deflection element  8  and second deflection element  10 , respectively.  
         [0016]    Thus, the three partial beams are so deflected in different ways by the first deflection element  8  that they strike the second deflection element  10  side by side (when looking in a direction transverse to the emission edge), hence their projections onto a plane, e.g. formed by the directions of the emission edge and of the beam, essentially coincide.  
         [0017]    However, a deflection can also be done in such a way that the projections essentially falls onto a plane which is inclined with respect to the plane formed by the directions of the emission edge and of the beam. A relevant task is to avoid a cross-over of the partial beams. According to the inventive concept it is possible to functionally integrate the deflection into the first deflection element  8  by means of design or to cause the deflection by additional elements which can be attached also to the first deflection element  8 .  
         [0018]    In the second deflection element  10  the partial beams are then so deflected in different ways that they strike the collimator  1  as if they all came from a line parallel or inclined to the emission edge in the focal plane of collimator  1  or, stated differently, in such a way that their back extrapolation will lead to such a line, and that each partial beam fills approximately one third of the aperture of collimator  1 . The three successive segments of the emission edge are imaged onto a nearly square field, and indeed in such a way that they are superimposed in the far field (FIG. 5). This secures an excellent target illumination.  
         [0019]    At wavelengths between 850 nm and 950 nm the beam can be collimated very strongly, allowing a range scan with high lateral resolution. Wavelengths around 1,550 nm are also very advantageous, since then the upper limit of the admissible single-pulse energy which is defined in terms of safety to the eyes has a value of about 8 mJ and thus is higher by a factor of about 16,000 than at wavelengths between 630 and 980 nm. By employing this factor at least in part, which becomes possible because of better beam concentration according to the invention, one can very substantially increase the range or, for a given range, raise the sensitivity.  
         [0020]    The mount  6  and the first deflection element  8  that is integral with it, as well as the second deflection element  10 , each are produced by one of the replication techniques as described in M. T. Gale, ‘Replication’, in H. P. Herzig (editor), ‘Micro-Optics’, Taylor &amp; Francis 1997, pp. 153-177, for instance by etching of a cylinder or piston of quartz and by hot embossing, injection molding, or casting followed by UV curing, and are then bonded to block  5 . The definition of the diffraction structures can be performed with known computer programs. The replication technique allows large numbers of parts to be fabricated at favorable cost. Since the mount  6  is also made by this technique, a very precise positioning of cylindrical lens  7  is possible. The tolerated variation of distance between the lens and the first deflection element  8  is a few micrometers. Using soldering and active adjustment as described in DE-A-197 51 352, the laser diode  3  can then be bonded in such a way to the beam forming optics  4  that the tolerated variation of mounting between it and the cylindrical lens  7  is about 0.5 μm.  
         [0021]    Various modifications of the embodiment described are possible. Thus, the cylindrical lens may be fastened with cement directly to the laser diode. The first deflection element and the second deflection element may also consist of glass, and for instance be made by an etching process. They may also be etched directly into the block separating them. The number of fields in the deflection elements may be two, four or more, instead of three. The beam forming optics may consist of refracting elements, for instance prisms and plates.  
         [0022]    Finally, laser diodes having wavelengths particularly between 600 nm and 1,000 nm, and more particularly between 630 nm and 980 nm which are outside the regions indicated above can be employed.  
         [0023]    List of Reference Symbols  
         [0024]    [0024] 1  Collimator  
         [0025]    [0025] 2  Light source  
         [0026]    [0026] 3  Laser diode  
         [0027]    [0027] 4  Beam forming optics  
         [0028]    [0028] 5  Block  
         [0029]    [0029] 6  Mount  
         [0030]    [0030] 7  Cylindrical lens  
         [0031]    [0031] 8  first deflection element  
         [0032]    [0032] 9   a,b,c  Fields  
         [0033]    [0033] 10  second deflection element  
         [0034]    [0034] 11   a,b,c  Fields