Frequency multiplication processing method and device

The invention claimed is: 1. A frequency multiplication processing method, comprising the steps of: for two adjacent pulse signals output from an encoder, determining a first kind of pulse signals and a second kind of pulse signals to be inserted between the two adjacent pulse signals according to a time interval between the two adjacent pulse signals and a frequency multiplication value corresponding to a longitudinal resolution, wherein a sum of the number of the first kind of pulse signals and the number of the second kind of pulse signals is the total number of the pulse signals to be inserted between the two adjacent pulse signals; determining a period of the first kind of pulse signals to be inserted between the two adjacent pulse signals and a period of the second kind of pulse signals to be inserted between the two adjacent pulse signals; and inserting the first kind of pulse signals and the second kind of pulse signals between the two adjacent pulse signals according to the determined period of the first kind of pulse signals and period of the second kind of pulse signals. 2. The method of claim 1 , wherein determining a first kind of pulse signals and a second kind of pulse signals to be inserted between the two adjacent pulse signals comprises: determining a candidate first kind of pulse signals from the total number of pulse signals to be inserted between the two adjacent pulse signals, according to the time interval between the two adjacent pulse signals and the frequency multiplication value; determining a first kind of pulse signals from the candidate first kind of pulse signals according to a binary value corresponding to a remainder of the time interval and the frequency multiplication value; and using the total number of pulse signals to be inserted between the two adjacent pulse signals except the first kind of pulse signals as the second kind of pulse signals; wherein the candidate first kind of pulse signals is determined from the total number of pulse signals to be inserted between the two adjacent pulse signals according to the following equation: Y ( i )= M *(2* j+ 1)/2 i+1 wherein a (Y(i)−1)th pulse signal among the total number of pulse signals to be inserted is the candidate first kind of pulse signals, M is the frequency multiplication value, 0≦i<m, 0≦j<2 i , and m is a number of bits of the binary corresponding to the remainder of the time interval and the frequency multiplication value. 3. The method of claim 2 , wherein determining a first kind of pulse signals from the candidate first kind of pulse signals comprises: determining the value of an ith bit R(i) of the binary corresponding to the remainder of the time interval and the frequency multiplication value, and when R(i) is a particular value, determining the (Y(i)−1)th pulse signal from the candidate first kind of pulse signals as the first kind of pulse signals. 4. The method of claim 1 , wherein the period of the first kind of pulse signals and the period of the second kind of pulse signals is determined according to the following step: determining the period of the first kind of pulse signals and the period of the second kind of pulse signals according to the frequency multiplication value and the time interval. 5. A frequency multiplication processing device comprising: a processing module being configured to, for two adjacent pulse signals output from an encoder, determine a first kind of pulse signals and a second kind of pulse signals to be inserted between the two adjacent pulse signals according to a time interval between the two adjacent pulse signals and a frequency multiplication value corresponding to a longitudinal resolution, wherein a sum of the number of the first kind of pulse signals and the number of the second kind of pulse signals is the total number of the pulse signals to be inserted between the two adjacent pulse signals; a determining module being configured to determine the period of the first kind of pulse signals to be inserted between the two adjacent pulse signals, and the period of the second kind of pulse signals to be inserted between the two adjacent pulse signals; and a frequency multiplication module being configured to insert the first kind of pulse signals and the second kind of pulse signals between the two adjacent pulse signals according to the determined period of the first kind of pulse signals and period of the second kind of pulse signals. 6. The device of claim 5 , wherein the processing module is further configured to determine a candidate first kind of pulse signals from the total number of pulse signals to be inserted between the two adjacent pulse signals according to the time interval between the two adjacent pulse signals and the frequency multiplication value; determine a first kind of pulse signals from the candidate first kind of pulse signals according to a binary value corresponding to a remainder of the time interval and the frequency multiplication value; and use the total number of pulse signals to be inserted between the two adjacent pulse signals except the first kind of pulse signals as the second kind of pulse signals; wherein the processing module is further configured to determine a candidate first kind of pulse signals from the total number of pulse signals to be inserted between the two adjacent pulse signals according to the following equation: Y ( i )= M *(2* j+ 1)/2 i+1 wherein a (Y(i)−1)th pulse signal among the total number of pulse signals to be inserted is the candidate first kind of pulse signals, M is the frequency multiplication value, 0≦i<m, 0≦j<2 i , and m is a number of bits of the binary corresponding to the remainder of the time interval and the frequency multiplication value. 7. The device of claim 6 , wherein the processing module is further configured to determine the value of an ith bit R(i) of the binary corresponding to the remainder of the time interval and the frequency multiplication value, and when R(i) is a particular value, the processing module is further configured to determine the (Y(i)−1)th pulse signal from the candidate first kind of pulse signals as the first kind of pulse signals. 8. The device of claim 5 , wherein the determining module is further configured to determine the period of the first kind of pulse signals and the period of the second kind of pulse signals according to the frequency multiplication value and the time interval.