DE4032193C2 - - Google Patents

Description

The invention relates to an optoelectronic camera the preamble of claim 1.

The state of the art in CCD image sensors is currently the Kodak megafixel chip KAF 4200 with 2048 × 2048 image elements. The pixel size is 9 × 9 square micrometers, the sensor area is 18.4 × 18.4 mm ² . The price of this chip is $ 35,000-65,000 depending on the quality level. With real-time video (motion picture with 25 frames / second) and 8-bit gray value quantization, the data rate is 105 megabytes / second. A further increase in the number of pixels of monolithically integrated semiconductor image sensors does not seem to make much sense due to the large amount of data, the high data rate in real-time applications and the exponentially decreasing manufacturing yield with increasing chip area and number of pixels.

In the published patent application DE 37 33 593 A1 a Vorrich device for receiving an object, in particular for the purpose described its playback on the screen. Doing so an image sensor that is smaller than the image through the lens, slidably arranged in the image plane. By moving the image sensor in the image plane any section of the image field made visible will. The advantage is that they are visible made detail with very good reproduction quality and high resolution is reproduced. A disadvantage is with this device that not the entire image field can be seen at a glance that the change in the picture section takes a certain time and that the dimensions solutions and the weight based on the required object tives with a large field of view are relatively large.

Another way of increasing the resolution of electronic cameras is with the still video camera ProgRes 3000, which is based on the patent DE 38 37 063 C1. The image sensor is a 6.6 × 8.8 mm ² CCD chip with 580 lines of 499 elements each. The pixels are approximately 11 x 17 square microns in size. The CCD matrix is covered by a perforated mask, which leaves only an area of less than 3 × 3 square micrometers free per pixel. The sensor can be moved horizontally in up to 6 intervals and vertically in 4 intervals, which increases the number of pixels by a factor of 24 to almost 7 million pixels. The gradual displacement of the sensor is carried out by piezoelectric drives, which enable highly precise and fast scanning. In principle, an even higher resolution would be possible with even smaller mask apertures. The main limit here is the sensitivity to light, which decreases square with the smaller used pixel area. High image resolution and high frame rate are not possible with this camera at the same time, but only as an alternative through appropriate programming. (Kontron - Fir Menschrift ProgRes 3000, Phototechnik International 12/89 p. 84)

Electronic cameras with image intensifiers are also known, who are used at extremely low illuminance levels that can. By driving with high voltage pulses an image intensifier for the electro-optical short-term shutter. With an appropriately designed and one suitable pulse generator supplied near focus image intensifier You can reach opening times in the nanosecond range chen. The SV-553 camera has 2 nanoseconds as the shortest Opening time on (Phototechnik International 4/89 p. 46).

In the published patent application DE 29 14 803 A1, the station wagon Nation of channel plate and CCD sensor patent pending. At a photocatode are struck by light quanta Generates electrons. These are caused by an electrostatic High-voltage field accelerated and by secondary electrons multiplication amplified in a microchannel plate. Collector Gate electrodes at the output of the individual channels of the micro channel plate catch the electrons and transfer them Memory, transfer element and analog shift register of the Processing too. The resolution of image intensifiers is limited. When using microchannel plates, this will be Resolving power through the center distance of the individual  Channels determined. It is currently around 20 µm. With Microchannel plates are electron amplification factors from 10,000 reachable.

The aim of the invention is to create an optoelectro African camera that enables high-resolution images (up to 500 pixels per millimeter), without sensitivity loss compared to known image sensors in real time (25th Frames per second), and the amount of data for the automatic image processing to the required level restrict.

The invention is based on the problem, the disadvantages the known application of the piezo-controlled aperture ver shift, low sensitivity and lack of real time ability to eliminate at high resolution.

The reason for the low sensitivity of the image sensors that work according to the piezo-controlled aperture shift is the reduction in the effective pixel area by masking, which is associated with a reduction in the proportion of the sensitive area in the total area of the sensor. In the case of real-time requirements, the sensitivity is indirectly further reduced in that the exposure time per pixel is limited in accordance with the frame rate and the number of steps per image. This results in
x = factor for increasing the horizontal resolution,
y = factor for increasing the vertical resolution
with the same frame rate, integration time = 1 / step frequency, as well as complete and coverage-free scanning of the sensitive area of the pixels, the factor K for reducing the sensitivity compared to the unmasked sensor.

K = (x _* y) ²

This factor is therefore the measure of the required ver Strengthening to compensate for the loss of sensitivity. With x = y = 10 results in a gain factor of 10,000. This object is achieved in a generic device solved by the characterizing features of claim 1.  

The lack of real-time capability at high resolution is on the limited data rate of the CCD image sensor and on it attributable to the fact that the entire image is always read out got to. The increase in image processing also comes across Data rate to technical and economic limits. At 25 Frames per second, 25 million pixels and 8-bit Gray value quantization results in a data rate of 5 giga bits per second. On the other hand, the high resolution is for the Image processing only partially necessary and useful. Around The real-time capability can be guaranteed after a further development of the invention, on the one hand, the entire Image captured with normal resolution and on the other hand Excerpts of the image can be accessed, that is, that the entire image does not have to be read out.

The device according to the invention and the invention Procedures enable the taking of pictures of an ob jektes with normal resolution and the recording high resolution the drawing files in real time with a minimum of image data.

The new technical principle is the same as that of the human Comparable to the eye. The entire object field becomes relative low resolution detected. The main parts of the picture Object are determined and with much higher up solution added. The object is seen by the eye with a localized "sharp look" in the resolution gropes. The visual process can be clearly visualized when measuring follow a ruler. The length of a route is thereby determines that only the start and end point of the route to be aligned with marks of the ruler and the distance is read on the scale.

The amount of data to be processed can be based on this principle in the automatic image processing by a preprocessing processing or selection can be drastically reduced.

The recording of an image section with variable size, Location and resolution is made possible.

The sensitivity of the optoelectronic camera can be by varying the acceleration voltage in height and Length of the impulses within certain limits to the circumstances to adjust.

Furthermore, the sensitivity can be at the expense of the maxi  Increase the resolution by combining several pixels be grasped.

The usable scope within the dependency on resolution solution, sensitivity, number of pixels and image fre quenz is with the optoelectronic invention Camera significantly expanded. According to the requirements the camera can be used in a wide variety of conditions be adjusted.

With the advantages mentioned, there is a wide range of uses field in the fields of automation and measurement technology, image processing, television technology and Satellite remote sensing.

Electronic television can be used in television technology Select the cut using the "mouse" or automatically (Pan, tilt, zoom).

The invention is hereinafter in connection with the enclosed ing drawing using exemplary embodiments explained in more detail. Show it:

Figure 1 is a representation of the device according to the invention in the main section.

Figure 2 is an illustration of the method for operating the device according to the invention.

Fig. 3 is a block diagram for controlling a device OF INVENTION to the invention;

FIG. 4 shows the time course of essential control signals in the operating mode overall image acquisition;

Fig. 5 shows the time course of essential control signals in the partial image acquisition mode.

In a first embodiment, corresponding to FIG. 1 and FIG. 3 to 5, a lens designs in its image plane (13) the optical image of an object. In the image plane of the lens there is a shadow mask ( 1 ), which has a regular hole structure ( 2 ) with a hole diameter of 5 micrometers, a hole spacing in the horizontal and vertical direction of 20 micrometers and a number of 512 x 512 holes. The shadow mask is applied to the photo cathode ( 3 ) of an image intensifier, which also consists of a microchannel plate ( 4 ) with 512 × 512 microchannels, which are arranged so that each hole of the mask is assigned a microchannel. On the output side of the image intensifier there is an xy-addressable image sensor ( 6 ), the pixels of which are formed as a collector electrode ( 5 ), which collect the electrons emitted by the individual microchannels and feed them to a storage capacitor. Each microchannel is in turn assigned a collector electrode and thus a pixel of the image sensor. The image intensifier and the surface of the image sensor are in a vacuum.

A high voltage source ( 7 ) supplies DC voltage pulses, the amplitude and length of which is variable. With these pulses, the image intensifier is operated in the manner of an electronic shutter.

Hole mask, image intensifier and x-y-addressable image recording mer are firmly connected and are relative to optical imaging of the object by two piezotranslators Step in the x and y directions a maximum of 4 · 5 µm each deflected wisely, in such a way that the figure is scanned seamlessly.

The pixels of the image sensor are addressed by Address decoder and MISFET switch. The x-y addressable Image sensor has the peculiarity that the pixels together and regardless of whether they were read out, can be reset.

The block diagram ( FIG. 3) shows the arrangement in a highly simplified manner, the assemblies analog amplifiers, filters (in particular suppression of the fixed pattern noise) and A / D converters are not explicitly designed. The abbreviations used mean:

A. . . High = image acquisition (exposure),
Low. . . Read out
MR. . . Reset signal for all pixels
V _BV . . . Control voltage for the image intensifier
ADBA. . . Pixel addresses of the image sensor
ADBS. . . Memory addresses of the image memory
T 1 , T 2 , T 3 . . . different clock signals

In the overall image acquisition mode ( FIG. 4), the arrangement is operated in the following manner: For an image, an image area of 20 μm × 20 μm is scanned in 4 × 4 steps in a meandering manner.

The arrangement is synchronized with high-voltage pulses acted on, so that a charge image in the image sensor the integration of 16 subpictures is created. The integra tion time is determined exclusively by the as electro African shutter operated microchannel plate determined. The meandering scanning means that between two Subpictures the arrangement by only one step (5 µm) must be moved further, so their positioning time mini is lubricated.

The x-y addressable image sensor is read out regularly line by line in a downstream image memory, which is not part of the device according to the invention. The assigned addresses of the pixels of the x-y address sizable image sensor and the memory cells of the image except for the offset of the image memory area identical.

In contrast z. B. to CCD image sensors run image integration and readout in the described xy-addressable image sensor from one after the other. This has the consequence that the light sensitivity is reduced by the factor T _A / T _B (T _A is the image acquisition time, T _B is the image acquisition time, i.e. image acquisition time plus image readout time) multiplied by the duty cycle of the voltage V _BV Example with a factor of 0.2. This loss of sensitivity is easily compensated for with the image intensifier.

In the partial image acquisition mode, an image area of 20 µm x 20 µm is also scanned in 4 x 4 steps with the aid of the shadow mask, but not meandering, but line by line, always starting with the 1st column, since the positioning, as shown in Fig . 5 ersicht required, adjust critical. In contrast to the overall image acquisition mode described above, after each raster step and the corresponding recording of a subimage of 128 × 128 pixels, this is read out into an image memory ( FIG. 5). The address is generated on the basis of the coordinate designating the image section (address of the upper left pixel of the sub-picture) so that after reading out a line of the sub-picture (128 pixels), the next line is jumped to with an offset of 384.

The address generation for the image memory takes place in the Way that only every sixteenth memory cell is written becomes. In the intermediate memory cells are after the other 15 sub-images were scanned. The last 4 bits of the memory address correspond to the current number mer of the subpicture within a picture with increased Resolution. The subpictures in the image memory thus become an image with 16x resolution nested.

In this operating mode there is the time-dependent and the loss of sensitivity due to area. The area-related te loss of sensitivity is calculated from the reciprocal the number of sub-pixels per picture element. The time-dependent Loss of sensitivity is calculated as follows:

For

x. . . Number of subpixels / picture elements in the x direction
y. . . Number of subpixels / picture elements in the y direction
s. . . Number of pixel columns of the imager
e.g. . . Number of pixel lines of the image sensor
T _p . . . Readout time for one pixel
T _A. . . Recording time for a sub picture

This results in the factor 0.02154 for this exemplary embodiment with T _p = 100 ns, T _B = 40 ms. Multiplied by the area-related factor 1/16 results in a sensitivity reduction to 1/743, which has to be compensated for by an appropriate gain setting of the image intensifier.

Another operating mode partial image acquisition with reduced Dissolution is also possible. It represents a combination of the operating modes total image capture and partial image capture This enables the holes with a shadow mask have smaller diameters (e.g. 2.5 µm), images vary resolution (number of pixels per picture element) to take.

A second, independent of the first embodiment,  Embodiment contains a shadow mask with a hole diameter of 2.5 µm, the one with 8 · 8 steps The number of pixels can be increased by a factor of 64 light. The image can have a maximum of 4096 x 4096 pixels be solved. 0.625 ms are available for each sub-picture when 64 pixels in 40 ms (25 Hz frame rate) should be recorded step by step.

This time is divided into the overall images operating mode the time for the relative movement of the shadow mask 2.5 µm, in the exposure time and in the readout time for the integrated image after a full cycle of mechanical scanning. With a movement time of 0.2 ms per step, an exposure time of 0.025 ms and one Readout time of 25.6 ms per image is a step frequency 4.5 kHz and a pixel readout frequency of 10.24 MHz required.

In the partial image acquisition mode, relative movement can and readout take place simultaneously. With a movement time of 0.2 ms stand for 0.425 ms for the same frame rate Exposure available. The cadence is reduced to 1.6 kHz. In the 0.2 ms for reading the Sub-images are available, 2048 pixels can be read out will. The partial image that can be read out in 40 ms exists with this Movement time from a maximum of 2048 x 64 pixels.

The length of an object ( 12 ) is measured as illustrated in FIG. 2. Each pixel ( 10 ) can be occupied with coordinates which identify its position within the coordinate system ( 9 ) of a pixel ( 11 ) and the position of this coordinate system in the reference coordinate system ( 8 ) of the semiconductor matrix structure. From the overall picture, the parts of the picture are determined that are essential for the dimension to be determined. Only these parts of the image are captured with maximum resolution. With the determined coordinates of the relevant pixels, the dimension can be determined using vector calculation.

In a third embodiment, the pixel Addressing in the image sensor using digital slides register. These have the peculiarity, forward and Allow pushing backwards. In the operating mode part  image acquisition becomes a meandering one Read out the pixels around the desired position light after the register has been brought into this position de. The meandering reading is in the address genes ration for the image memory is taken into account.

Claims (14)

1. Optoelectronic camera with piezo-controlled aperture shift for obtaining high-resolution electronic images consisting of a lens that images an object in an image plane, a shadow mask that lies in the image plane and has a regular hole structure, the dimensions of the holes being a measure of the achievable resolution , an image sensor which is located behind the shadow mask and which generates the converted image in the form of charges and piezoelectric drives which enable the relative displacement between the shadow mask and the image in the image plane with high speed and precision, and corresponding control electronics, characterized in that between the shadow mask and image sensor an image intensifier is arranged, which uses the radiation falling through the shadow mask onto the photo cathode of the image intensifier to generate electrons, which are reproduced and / or accelerated, so that indirectly or directly d A charge structure corresponding to the radiation falling through the shadow mask is generated by the image sensor. 2. Device according to claim 1, characterized in that the image sensor is x-y addressable. 3. Device according to claim 1, characterized in that the image intensifier as part of a microchannel plate and that each hole of the shadow mask has a microchannel assigned. 4. Apparatus according to claim 1 and 3, characterized in that directly behind each microchannel is a collector electrode is arranged which enables the electrons to be directly feed into the image sensor. 5. The device according to claim 1, characterized in that the image intensifier has a fluorescent screen, which with the Image sensor is connected, which means indirectly via light quantum a charge image is generated.   6. The device according to claim 1 and 2, characterized in that the smallest part of the image that can be read out through the step grid the drives and the hole diameter of the shadow mask becomes. 7. The device according to claim 1 and 3, characterized in that the control of the microchannel plate as high voltage is formed, the pulses of variable length Control of integration time can provide. 8. The device according to claim 1 and 7, characterized in that that the level of the pulse voltage of the high voltage source to The purpose of the gain control is variable. 9. Method of operating the optoelectronic camera since characterized in that in the overall images mode the essential parts of the picture are determined and in the Be Drive mode partial image capture the particular or other image parts can be detected with higher resolution, the Select the operating mode and the image section manually or can be done automatically. 10. Procedure in the overall image acquisition mode Claim 9, characterized in that the resulting Charge image of the x-y addressable image sensor during a complete cycle of mechanical scanning is integrated and read out pixel by pixel, so that the number the pixels of the scanned image, the number of pixels of the x-y addressable image sensor. 11. Procedure in the overall image acquisition mode Claims 9 and 10, characterized in that the inte in equal parts to the individual Raster steps within a complete cycle of the mechanical scanning is divided. 12. Procedure in the operating mode field acquisition according to An Proverb 9, characterized in that only limited picture parts are read out, which are free per location and size  are grammable. 13. Procedure in the combination of the operating modes total Image capture and partial image capture according to claim 9, 10, 11 and 12, characterized in that the resulting charge image of the x-y addressable image sensor during a complete cycle of mechanical scanning is integrated pixel by pixel, so that the number of pixels of the scanned image is a multiple of the number of Read out pixels of the x-y addressable image sensor corresponds. 14. The method according to claim 9, 10 and 12, characterized in net that each pixel can be assigned coordinates, its location within the coordinate system of a pixel of the x-y addressable image sensor and the position of this Coordinate system in the reference coordinate system of the x-y address markable image sensor, whereby the determ the distance between individual pixels whose partial images are made possible by means of vector calculation.