Patent Number: 
Section: claims

1. A method for characterizing the vibrational performance of a charged particle beam microscope system having at least one encoder, comprising:providing a plurality of images taken by using said charged particle beam microscope system, said images comprising at least one imaged pattern, each said image being taken at a predefined set of encoder frequencies; andcorrelating said encoder frequencies with a vibration amplitude of said imaged pattern in said images. 2. The method of claim 1, wherein said correlating step comprises:generating, for each said image, a time-domain image vibration signal representing information of said imaged pattern vibration amplitude versus an elapsed time period of concerned said image being taken;generating, for each said image, a frequency-domain image vibration spectrum from said time-domain image vibration signal, said frequency-domain image vibration spectrum representing information of said imaged pattern vibration amplitude versus a range of frequencies including said set of encoder frequencies;identifying, for each said image, from said frequency-domain image vibration spectrum, at least one said encoder frequency from said set of encoder frequencies each with a corresponding said imaged pattern vibration amplitude, so as to form at least one data pair accordingly; andforming, using said data pairs, points on a coordinate system of imaged pattern vibration amplitude versus frequency thereby forming a system vibrational performance chart characterizing said vibrational performance of said charged particle beam microscope system, whereinsaid vibrational performance represents said imaged pattern vibration amplitude in individual said image at at least one said encoder frequency from said set of encoder frequencies at which concerned said image is correspondingly taken by using said charged particle beam microscope system. 3. The method of claim 1, wherein provided said images are taken by using said charged particle beam microscope system in a continuous scan mode operation. 4. The method of claim 1, wherein each said set of encoder frequencies corresponds to a predefined imaging condition which comprises one selected from the group consisting of the following, or any combination thereof: pixel size, average number of scan of said sample in a point or line level, and the length of charged particle beam scan lines, a sampling rate of the imaging channel of the charged particle beam microscope system. 5. The method of claim 1, wherein each said set of encoder frequencies includes an encoder primary frequency and at least one encoder harmonic frequency derived from said encoder primary frequency. 6. The method of claim 1, wherein said encoder is part of a closed-loop control system controlling the motion of a moving stage whereupon a sample is secured for imaging, for providing a feedback signal indicating the instant moving speed of said stage. 7. A computing agent for characterizing the vibrational performance of a charged particle beam microscope system, said charged particle beam microscope system having at least one encoder, comprising:an input member able to be coupled to said charged particle beam microscope system for receiving, from said charged particle beam microscope system, a plurality of images formed by said charged particle beam microscope system and information of a plurality of sets of encoder frequencies, each said image being formed at a corresponding said set of encoder frequencies, said images comprising at least one imaged pattern;a computing member coupled with said input member for receiving said images and information of encoder frequencies from said input member, said computing member executing the following steps:generating, for each received said image, a time-domain image vibration signal representing information of a vibration amplitude of said imaged pattern versus an elapsed time period of concerned said image being formed;generating, for each received said image, a frequency-domain image vibration spectrum from said time-domain image vibration signal, said frequency-domain image vibration spectrum representing information of said imaged pattern vibration amplitude versus a range of frequencies including said set of encoder frequencies;identifying, for each received said image, from said frequency-domain image vibration spectrum, at least one said encoder frequency from said set of encoder frequencies each with a corresponding said imaged pattern vibration amplitude, so as to form at least one data pair accordingly; andforming, using said data pairs, points on a coordinate system of imaged pattern vibration amplitude versus frequency thereby forming a system vibrational performance chart characterizing said vibrational performance of said charged particle beam microscope system, whereinsaid vibrational performance represents said imaged pattern vibration amplitude in individual said image at least one said encoder frequency from said set of encoder frequencies at which concerned said image is formed by said charged particle beam microscope system; andan output member coupled with said computing member for receiving said system vibrational performance chart from said computing member and outputting the same for the user's interpretation. 8. The computing agent of claim 7, wherein said computing member further executes the following step:selecting a plurality of imaging conditions, each said imaging condition corresponding to one of said sets of encoder frequencies;causing, through said input member or an additional interface, said charged particle beam microscope system to form said images according to said selected imaging conditions. 9. The computing agent of claim 8, wherein said imaging conditions are obtained as a user input through a user input means on said computing agent, said charged particle beam microscope system, or both. 10. The computing agent of claim 9, wherein said imaging conditions are pre-stored in a storage medium in said computing agent. 11. The computing agent of claim 7, wherein said images are formed by said charged particle beam microscope system in a continuous scan mode operation. 12. The computing agent of claim 7, wherein said encoder is part of a closed-loop control system controlling the motion of a moving stage whereupon a sample is secured for imaging, for providing a feedback signal indicating the instant moving speed of said stage. 13. The computing agent of claim 7, wherein said input member is coupled to said charged particle beam microscope system through a medium selected from a group consisting of the following, or any combination thereof: cable wire, optical fiber cable, portable storage media, IR, Bluetooth, human manual input, intranet, internet, wireless network, wireless radio. 14. The computing agent of claim 7, wherein each said set of encoder frequencies includes an encoder primary frequency and at least one encoder harmonic frequency derived from said encoder primary frequency. 15. A charged particle beam microscope system having at least one encoder, comprising:a moving stage whereupon a sample is secured for imaging;a charged particle beam generator for generating a primary charged particle beam;a condenser lens module for condensing said primary charged particle beam;a probe forming objective lens module for focusing condensed said primary charged particle beam into a charged particle beam probe;a deflection module for scanning said charged particle beam probe across a surface of said sample;a detector module for collecting charged particles generated from said sample surface upon bombardment of said charged particle beam probe and generating a detection signal accordingly;an image forming module coupled with said detector module for receiving said detection signal from said detector module and forming at least one charged particle microscopic images accordingly; anda vibration characterization module for characterizing the vibrational performance of said charged particle beam microscope system by correlating working frequencies of said encoder with corresponding vibration amplitudes of an imaged pattern in said images. 16. The charged particle beam microscope system of claim 15, wherein said vibration characterization module is coupled with said image forming module and said encoder, and is encoded with a computer program, said computer program caused said vibration characterization module to perform the following steps:retrieving, from said image forming module, a plurality of images taken by using said charged particle beam microscope system, each said image comprising at least one imaged pattern;receiving, from said encoder, a plurality sets of encoder frequencies from said encoder, each said image being taken at a predefined said set of encoder frequencies;generating, for each said image, a time-domain image vibration signal representing information of said imaged pattern vibration amplitude versus an elapsed time period of concerned said image being taken;generating, for each said image, a frequency-domain image vibration spectrum from said time-domain image vibration signal, said frequency-domain image vibration spectrum representing information of said imaged pattern vibration amplitude versus a range of frequencies including said set of encoder frequencies;identifying, for each received said image, from said frequency-domain image vibration spectrum, at least one said encoder frequency from said set of encoder frequencies each with a corresponding said imaged pattern vibration amplitude, so as to form at least one data pair accordingly; andforming, using said data pairs, points on a coordinate system of imaged pattern vibration amplitude versus frequency thereby forming a system vibrational performance chart characterizing said vibrational performance of said charged particle beam microscope system, whereinsaid vibrational performance represents said imaged pattern vibration amplitude in individual said image at least one said encoder frequency from said set of encoder frequencies at which concerned said image is formed by said charged particle beam microscope system. 17. The charged particle beam microscope system of claim 15, wherein received said images are formed by said charged particle beam microscope system in a continuous scan mode operation. 18. The charged particle beam microscope system of claim 16, wherein each said set of encoder frequencies corresponds to a predefined imaging condition which comprises one selected from the group consisting of the following, or any combination thereof: pixel size, average number of scan of said sample in a point or line level, and the length of charged particle beam scan lines, a sampling rate of the imaging channel of the charged particle beam microscope system. 19. The charged particle beam microscope system of claim 18, further comprising a user input means for loading said imaging condition into said charged particle beam microscope system as a user input. 20. The charged particle beam microscope system of claim 15, wherein said encoder is part of a closed-loop control system controlling the motion of said stage, for providing a feedback signal indicating the instant moving speed of said stage.