This invention relates to optical system design, more specifically to lens design, image chip design and lens module design.
Optical systems are increasingly penetrating into our everyday life. Digital Cameras, Projectors, Camcorders, and new generations of cellular phones with cameras, just to name a few common products.
A typical optical system consists of a set of lens and an image chip.
The image chip is typically made of either CCD (charge-coupled-device) or CMOS (complementary-Metal-Oxide-Semiconductor). It senses the image formed by the lens set and converts it into electrical signals (either analog or digital).
The lens is made of plastics or glass with spherical or aspherical surface, it bends the light from the object and forms an image at the image plane. Plastic lens is very cheap but of less quality. Glass lens is used for optical systems with higher resolution and less temperature-related distortions. Glass lens is more expensive than plastic lens. Lens with spherical surface is much easier to manufacture and much cheaper than lens with aspheical surface.
There is no lens set that can form an exact image of the object, aberrations are always present in the images. For example, if the object is a point light source, its image will not be a point, rather the image will be a haze surrounding a bright point. The image of a point object is called Point-Spread-Function (PSF). The aberrations of lens are usually classified as: Spherical Aberration, Coma, Astigmatism, Distortion and Chromatic Aberrations. The Point-Spread-Function (PSF) contains all of these informations.
As shown in
Y′=A1S cos θ+A2h+B1S3 cos θ+B2S2h(2+cos 2θ)+(3B3+B4)sh2 cos θ+B5h3+C1S5 cos θ+(C2+C3 cos 2θ)s4h+(C4+C6 cos 2θ)s3h2 cos θ+(C7+C8 cos 2θ)s2h3+C10sh4 cos θ+C12h5+D1S7 cos θ+ (1)
X′=A1s sin θ+B1S3 sin θ+B2s2h sin 2θ+(B3+B4)sh2 sin θ+C1s5 sin θ+C3s4h sin 2θ+(C5+C6 cos 2θ)s3h2 sin θ+C9s2h3 sin 2θ+C11sh4 sin θ+D1s7 sin θ+ (2)
The objective of lens design is to choose from different glass material, choose the number of lens, the shape and size of each lens, so that the whole lens set meets the specifications including focal length, view angle, resolution, distortion, etc.
Traditionally, the lens design and image chip design are two independent processes done by independent companies. The lens designers optimize the lens design to achieve as less aberrations and distortions as possible, which usually results in many lens in high resolution systems (typically 3 to 12 lens). To reduce the number of lens, some manufacturers use aspherical lens (non-spherical surface) which is very expensive. On the other hand, the rapid advance in VLSI technology makes the digital-signal-processing capability of image chips very high with little cost. It is foreseeable that as technology advances, the resolution requirements of the lens system are increasingly higher which will put lots more burdens on the lens design. The essence of the invention is to make full use of the powerful digital-signal-processing-capability of the image chip to correct some aberrations of the lens set, thus reduce the aberration requirements for the lens design. By doing this, the number of required lens is reduced and the overall cost of the optical systems (lens+image chip) is reduced. That is, smaller and cheaper optical system can be achieved using this invention.
The invention is about the optimization of the optical system design (including both lens and image chip). Using the proposed design method for both lens and image chips, higher resolution with less cost and smaller size are possible.
Firstly, for existing lens, the Point-Spread-Functions of selected object points are measured (Refer to
Secondly, for optical systems of which the lens must be re-designed, much less cost and smaller size optical systems can be achieved by relaxing the aberration requirements on the lens system, that is, less number of lens can be used to achieve the desired high resolution using the proposed error correction techniques. This is extremely useful for cell-phones cameras, in which the camera must be made as small as possible.
Theoretically, the proposed aberration correction technique can be proven as follows.
As shown in
For each object point i, its intensity at image point j can be denoted as Sij, where Sij is a representation of the Point-Spread-Function.
For an arbitrary object, if the illuminance of the i-th object point is denoted by Oi, its image at j-th pixel is denoted by Ij, then using matrix format, the lens system can be described as:
Or to write it concisely in vector form:
I=S*O (3)
Ideally, for a perfect lens system, the S matrix is a unit matrix, that is, every object points corresponds to one image point. In reality the images are somewhat blurred.
If the lens aberrations are not too big, then the S matrix will be a sparse matrix, that is, there are only a few non-zero elements. For example, the first column stands for the Point-Spread-Function of the first object point. If the point-spread-function covers only 5 images points, then only the first 5 elements are non-zero.
Theoretically once S matrix is extracted from measurements, then for any light source, its true image can be derived from
O=S−1*I. Where S−1 is the inverse matrix of the S matrix. (4)
It should be noted that for different wave length lights, the S matrix will be slightly different because of the lens aberrations.
This is the essence of the invention, use some pre-designed object (one example is shown in
Another example of measuring the Point-Spread-Function of the lens is shown in
ε=Ri−(Li/Lo)*Ro
It should also be pointed out that by using both the measured S-matrix and the theoretical lens aberrations formulae (1) & (2), some faster image correction algorithms are possible.