Global process variations

Global process variations typically result from errors during the photolithographic processing and etching of the wafers. Similar to all photographic processes, the photo-lithographic processing of silicon is prone to over or under exposure, over or under development etc. Similarly, the etching steps, which follow the photolithographic process, are prone to over or under etching. Characteristics of global process variations are, that they are constant over the entire wafer, i.e. common to all components on the wafer. Typically, global process variations cause degradation of the circuit element matching.

  
Figure 2.2: Capacitor ratio example.

To examine the consequences of such processing errors and to see, how the resulting mismatch may be minimised, a pair of matched capacitors with the desired capacitor ratio is examined (see Figure 2.2). The area ratio for the capacitors drawn during layout is:
 
If the poly-silicon is over-etched by (such errors may occur due to variations in the etching time or from changing saturation of the etching fluid from one wafer batch to the next) then the realised capacitor ratio, , is given by:
 
Combining Equations 2.6 and 2.7, the relative error, , can be calculated to estimate the achievable matching:
 

The consequences of such errors can be illustrated by a typical example. Assume that a capacitor with dimension is used, and that typical etching variations must be accepted. The wavelength of blue light is approximately 460nm, thus an error of 100nm is less than one quarter of the wavelength. Despite the small magnitude of this error, it can result in serious problems in high precision circuits. For a capacitor ratio of 4:1, Equation 2.9 gives the following error:

If the two capacitors were to be used in a data converter, then this error would correspond to 6.2bits0.5bit of linearity. Evidently, the use of such simple structures is not appropriate for the design of precision circuits.

  
Figure 2.3: Using unit capacitors.

The error can be eliminated or at least dramatically reduced by the use of unit capacitors (see Figure 2.3). Using unit capacitors, the area of each capacitor is reduced by the same factor. Therefore, the ratio remains unchanged. The use of unit elements requires that the lowest common denominator of the desired ratio is feasible to implement.

  
Figure 2.4: Non-unit capacitor structure.

If the required ratio can not be achieved with a reasonable number of unit elements, then a non unit capacitor (or element) must be used. For example, a ratio of 11:13.3 requires 243 unit capacitors, which is not realistic. If non-unit capacitors are used, the matching is sensitive to global lithographic variations. Consequently, the capacitor ratio depends on such factors as over or under etching. The magnitude of these errors can be minimised with the use of optimum dimensioning (see Figure 2.4). A global etching error in this structure introduces the relative error, :
 

Equation 2.13 gives a good approximation for the mismatch due to etching errors. Now, this equation is used to find the dimensions for X₂ and X₃, which give the minimum sensitivity of to . The optimum is found by taking the first derivative of with respect to and setting the equation equal to zero:
 
The first term of Equation 2.14 is the ratio of the perimeters, and the second term is the ratio of the areas. If Equation 2.14 equals zero, then the ratio of the perimeters must equal the ratio of the areas. Solving this equation to find the optimum dimensioning for the capacitors gives:

Finally, solving the quadratic equation gives:
 

One restriction on the choice of non-unit capacitors can readily be seen from Equation 2.16. If the solutions to the quadratic equation are to be real, then the capacitor ratio must be greater than 1. This means that the smaller capacitor should correspond to the unit capacitor, and the larger capacitor should be the non-unit element. If Equation 2.16 is used to dimension the non-unit capacitors, then a layout is achieved, which has minimum sensitivity to photolithographic errors and etching variations.

The previously discussed example of a capacitor ratio 11:13.3 would be implemented using 11 unit capacitors for one capacitor and 12 units plus one non-unit for the second capacitor.

Unfortunately, this solution assumes isotropic etching. From Equation 2.16, long and narrow capacitors result for ratios and , when is small. Unfortunately, such capacitors are very sensitive to anisotropic etching and photolithographic processing.

Capacitors of value should be realised using a square capacitor. Similarly, capacitors in the range should be implemented as one unit capacitor and one capacitor of value . The increased sensitivity of these structures to isotropic errors is more than compensated by the improved performance with respect to anisotropic processing[O'L91].