This study has developed a clustering algorithm for spike sorting. It assumes that neuron signal waveform is different from each neuron when there is not overlapping and bursting in neuron signal. Based on the previous hypothesis, tetrode, which is an instrument detecting a neuron signal consisting of waveform resolution and spatial resolution. Waveform that is detected from a tetrode is consisting of neuron signals and noise. This study has pre-processed the linearity of tetrode waveforms, and filtered the signal out high frequency component which usually is noise. In order to amplify the difference between different neuron waveform, we further add the artifical detail component into the waveform in time domain. This process will output waveform with noise-reduced and detail-included. Finally, the principal component analysis (PCA) is applied to reduce number of dimensionality. The feature which is extracted from these previous methods is called LDPCA (low-pass difference PCA) feature. On the other hand, the spatial resolution is defined as the decay which is a result of spatial distance from neuron to tetrode based on signal transmitting model. In clustering computing, an unsupervised clustering algorithm, affinity propagation (AP), is employed, and the result of this algorithm can output an objective clustering result. Even in low SNR environment (about 3 dB), the clustering accuracy is still higher than 70%, and the accuracy is getting better when the SNR is getting higher. Another clustering algorithm, k-means, can’t improve the accuracy even in higher SNR environment (about 10 dB). One of the advantages of the spike sorting is to express the model of neuron spikes firing. An exponential probability distribution and the main parameter μ can be used to describe the firing model. The false rate of μ is lower than 20% when the spike number is more than 50. Excepting the developed clustering algorithm, the method of signal source localization based on planar tetrode signal has been developed. The co-planar tetrode is virtually shifted from the 2-D tetrode to 3-D tetrode in this method. The error of distance from localization can be considered as noise interference. In high SNR environment, we can clearly observe the distribution of the localized points. The root mean square error is less than 25 μm. The result shows that the method of localization can help biological researchers to estimate the performance of spike sorting result.