An improvement detecting method was proposed according to the disadvantages of testing method of optical axes parallelism of shipboard photoelectrical theodolite (short for theodolite) based on image processing. Pointolite replaced 0.2'' collimator to reduce the errors of crosshair images processing and improve the quality of image. What’s more, the high quality images could help to optimize the image processing method and the testing accuracy. The errors between the trial results interpreted by software and the results tested in dock were less than 10'', which indicated the improve method had some actual application values.
The optical axes parallelism is one of the vital indexes to evaluate the measurement precision of theodolite [
A testing method of optical axes parallelism of shipboard photoelectrical theodolite was proposed in reference [
In the former image processing method progress, CCDs were used to record the images or videos of the crosshair of 0.2'' collimator, and then the data stored in CCDs would be acquired by DAQ (Data Acquisition) cards and sent to computer, and the results would be calculated immediately. The whole progress was shown in
During the detecting processing, many factors such as hardware, experimental environment and the image processing calculation may affect the final result. According the analysis of factors mentioned above, some conclusion could come to as follows.
1) According to the imaging principle, the crosshair getting smaller when the axes of 0.2'' collimator further from the middle of Mid-Wave infrared visual field.
2) The CCD lens distortion was another crucial factor for the system precision.
3) The higher the resolution, the finer the detail that can be seen, error might be caused by resolution of image sensor in image acquisition system.
4) Noise source might cause noise during the images acquisition, which could not be denoise clearly.
5) In the process of image processing, many valid pixels might be lost, thus to improve the testing accuracy, optimized arithmetic should be applied.
The resolution of theodolite system was 0.44'', while the Mid-Wave infrared system was 15.5'', so the main factor that affected the system precision was image processing of Mid-Wave infrared system.
Actually, during the experiment, the crosshair of 0.2'' collimator imaging in the Mid-Wave infrared was blurring. The analysis result indicated that when crosshair reflect through 0.2'' collimator and 90˚ refracted collimator, the illuminance and thermal radiation underwent great loss, consequently, images could not meet the accuracy requirement.
Since images with low quality and image processing with low accuracy, some steps were taken to improvement light source and image processing method.
After theoretical analysis and study, two methods were intended to apply to replace 0.2'' collimator, which were laser combine with frequency multiplier and halogen tungsten lamp match with lens that can converge light [
The experiment was carried on in the early morning, when tide and crew’ activities had minimum effect on ship movement. Firstly, setting the testing support on the transition section of theodolite, and fixing the halogen tungsten lamp and lens in the testing support. Secondly, adjusting position between the lens and theodolite, till the point light in the vision field of Mid-Wave infrared CCD. Thirdly, adjusting the 90˚ refracted collimator to support the point light into the vision field of theodolite CCD. And then, turning the computer power on, the camera link DAQ card and LVDS DAQ card started to acquire the images and store in the hardware. Finally, transmitting the point light imaged in the two systems to the software, where the middle of the point light would be calculated.
By compared many advanced methods on image processing, the adaptive gradient threshold anisotropic filtering algorithm was chosen to suppress the infrared complex back-ground [
The optical axes parallelism could be expressed as follow formula according to principle of optical system [
wherein,
The data in
Pixels record times | Theodolite | Mid-Wave infrared | Optical axes parallelism ('') | |||
---|---|---|---|---|---|---|
x1 | y1 | x2 | y2 | ΔX | ΔY | |
1 | 254 | 116 | 8 | 5 | −12.24 | −26.46 |
2 | 264 | 121 | 9 | 5 | −23.34 | −24.26 |
3 | 248 | 90 | 8 | 4 | −14.88 | −22.4 |
4 | 260 | 85 | 9 | 4 | −25.1 | −24.6 |
Relationship between optical axes parallelism of the two optical systems and angle measurement error could be expressed as Formula (2) [
wherein,
Image processing method was the key technology which had main effect on detection accuracy. A video and image processing software was used to detect the images which also processed by the improvement image processing method. The software could judge the change of miss distance of target by dealing with continuous frames images, which would help to eliminate the error caused by small displacement of target. The judgement of software had two methods, which were manual and automatic. Manual way was used to process fine and homogeneous target, which could achieve high image processing precision. The experiment was carried on under quasi-static condition, as a result, the ship swung periodically, similarly, the miss distance of target was periodic. The square root of the average of squares of miss distance could truly reflect the position of target. The real-time result was shown in
Series images were proceed by sending to the software as shown in
the result of this experiment.
The experiment showed that the improvement detection method improved imaging quality and optimized the image processing steps, which ensured its high precision and real-time performance. The follow-up work was accuracy verification, which should be carried out in the four quadrants of CCD, and accuracy verification results determined according to the consistency of the error.
Zou, H.H. (2017) Improvement Detecting Method of Optical Axes Parallelism of Shipboard Photoelectrical Theodolite Based on Image Proces- sing. Optics and Photonics Journal, 7, 127- 133. https://doi.org/10.4236/opj.2017.78B017