Patent Number: 
Section: claims

1. An electron energy loss spectral observation apparatus comprising:a transmission or scanning transmission electron microscope;an electron spectrometer having a plurality of lenses; andan electron spectrometer controller for controlling the electron spectrometer,wherein the electron spectrometer controller includes:simulation means based on a parameter design method using, as parameters, exciting current values of the individual lenses or values set on the basis of the exciting current values, for simulating fluctuation of electron energy loss spectral data when a plurality of parameters of the individual lenses are fluctuated simultaneously and conditions of the individual lenses are decided by calculation values based on the simulation result. 2. The electron energy loss spectral observation apparatus according to claim 1, wherein the simulation means is configured to implement functions, including functions to:allot the parameters to a orthogonal array;acquire electron energy loss spectral data in accordance with individual conditions based on the orthogonal array;prepare a factor effect table on the basis of electron energy loss spectral data corresponding to the individual conditions; andcalculate optimum parameters from the factor effect table. 3. An electron microscope comprising:an electron spectrometer having a plurality of lenses and adapted to perform energy spectroscopy; anda lens adjustment system for adjusting the lenses,wherein the lens adjustment system controls conditions of the individual lenses based on a simulation of fluctuation of electron energy loss spectral data when a plurality of exciting currents or values set on the basis of the exciting currents are fluctuated simultaneously. 4. The electron microscope according to claim 3,wherein the lens adjustment system sets conditions of the individual lenses through simulation based on a parameter design method using, as parameters, exciting currents or values set on the basis of the exciting currents. 5. The electron microscope according to claim 4, wherein the lens adjustment system is configured to perform implement functions, including functions to:read input values of the parameters;allot the parameters to an orthogonal array;acquire spectral data corresponding to conditions based on the orthogonal array;prepare a factor effect table from the acquired spectral data;calculate conditions of exciting currents of the individual lenses from the factor effect table: andcontrol the exciting currents of the individual lenses on the basis of the calculated exciting current values of the individual lenses. 6. The electron microscope according to claim 4, further comprising:an image display unit for displaying spectral data of the electron microscope, wherein:the image display unit displays a lens adjustment button for starting adjustment of lens conditions on the image display screen, andthe lens adjustment system is started in accordance with a command via the lens adjustment button. 7. The electron microscope according to claim 4, wherein:at least any one of the parameters is a fixed value set during production of the apparatus or installation thereof,at least any one of the other parameters is a variable value to be set during adjustment, andthe lens adjustment system adjusts a lens corresponding to the variable value. 8. A lens adjustment method including simulation means configured to implement functions, including functions to:adjust optimum conditions of a plurality of lenses, wherein exciting currents of the individual lenses or values set on the basis of the exciting currents are used as parameters; andcarry out simulation based on a parameter design method, wherein:conditions of exciting currents of the individual lenses are set on the basis of calculation values based on the simulation. 9. A lens adjustment method comprising steps of:adjusting optimum conditions of a plurality of lenses of an electron spectrometer attached to an electron microscope and adapted to perform energy spectroscopy, wherein exciting currents of the individual lenses or values set on the basis of the exciting currents are used as parameters; andcarrying out simulation based on a parameter design method, whereinconditions of exciting currents of the individual lenses are set on the basis of calculation values based on simulation of fluctuation of electron energy loss spectral data for fluctuation of parameters of the individual lenses. 10. The lens adjustment method according to claim 9, wherein the step of carrying out simulation comprises:reading parameters of each lens,allotting the parameters to an orthogonal array,acquiring spectral data in accordance with conditions based on the orthogonal array,preparing a factor effect table from the acquired data, andcalculating conditions of exciting currents of the individual lenses on the basis of the factor effect table. 11. A lens adjustment system for adjusting conditions of a plurality of lenses of an electron spectrometer, the system comprising:simulation means based on a parameter design method using, as parameters, exciting current values of the individual plural lenses or values set on the basis of the exciting current values, wherein:of a group of the lenses, the simulation means sets a lens with fixed parameters and sets another lens is set with unfixed parameters, and during lens condition adjustment, andconditions of the lens for which the parameters are unfixed are adjusted on the basis of calculation values based on simulation of fluctuation of electron energy loss spectral data for fluctuation of parameters of the individual lenses by the simulation means. 12. A lens adjustment method comprising steps of:adjusting exciting current values of individual lenses of an electron spectrometer by setting at least three parameters based on exciting current values for each lens and a number of simulation operations; andconducting simulation on the basis of the set values, wherein the simulation includes:inserting three parameters based on the exciting current values, as parameters of the individual lenses, to an orthogonal array;measuring a zero-loss spectrum under the individual conditions based on the orthogonal array;calculating a half-width of the measured zero-loss spectrum;preparing a factor effect table from the half-width corresponding to each calculated condition;acquiring a relational expression between the exciting current value of each lens and the half-width from the factor effect table; andcalculating the exciting current value of each lens from the relational expression,wherein the simulation is repeated in accordance with a frequency of the simulation by using the calculated exciting current value as an initial value. 13. A controlling apparatus for an electron spectrometer comprising a plurality of lenses, wherein:the apparatus is configured to adjust exciting current values of individual lenses of the electron spectrometer including a plurality of lenses, the exciting current values of individual lenses of the electron spectrometer being adjusted by the apparatus through simulation based on at least three parameters based on exciting current values for each lens and the number of simulation operations, wherein the simulation includes the functions to:insert three parameters based on the exciting current values, as parameters of the individual lenses, to an orthogonal array;measure a zero-loss spectrum under the individual conditions based on the orthogonal array;calculate a half-width of the measured zero-loss spectrum;prepare a factor effect table from the half-width corresponding to each calculated condition;acquire a relational expression between the exciting current value of each lens and the half-width from the factor effect table; andcalculate the exciting current value of each lens from the relational expression,the controlling apparatus being further configures to set the exciting current value of each lens by repeating the simulation in accordance with a frequency of the simulation by using the calculated exciting current value as an initial value. 14. The controlling apparatus according to claim 13, further comprising:a storing apparatus for storing at least one of the initial value and the calculated exciting current value by the simulation. 15. An electron microscope comprising the controlling apparatus according to claim 14. 16. An electron energy loss spectral observation apparatus comprising the controlling apparatus according to claim 14. 17. An electron microscope comprising the controlling apparatus according to claim 13. 18. An electron energy loss spectral observation apparatus comprising the controlling apparatus according to claim 13.