Patent Number: 
Section: claims

1. An autoadjusting electron microscope comprising: a specimen stage for holding a specimen;  an electron gun for emitting a first electron beam;  an electron lens for irradiating the specimen with the first electron beam;  a deflector for deflecting the first electron beam such that an incident angle at which the first electron beam is incident on the specimen changes from a first incident angle to a second incident angle;  a detector for detecting a second electron beam generated by irradiation of the specimen with the first electron beam;  a storage for storing a first image obtained by the detector when the first electron beam is incident on the specimen at the first incident angle and a second image obtained by the detector when the first electron beam is incident on the specimen at the second incident angle;  an image processor for deriving a third image constituting an analysis image from the first image and the second image;  a computer for determining an amount of displacement between the first image and the second image based on a peak appearing in the third image;  an identifier for determining whether a consistency between the first image and the second image is within a predetermined range based on a magnitude of the peak appearing in the third image; and  a transformer for transforming results obtained by the computer and the identifier into an amount of defocus of the electron lens relative to the specimen. 2. An autoadjusting electron microscope according to  claim 1 , wherein at least two peaks appear in the third image; and claim 1 wherein the autoadjusting electron microscope further comprises a selector for selecting one of the at least two peaks appearing in the third image based on an occurrence of a peak at a location in the third image corresponding to a situation where the first image matches the second image. 3. An autoadjusting electron microscope according to  claim 1 , wherein the computer determines the amount of displacement between the first image and the second image to a precision of less than one pixel of the first image and the second image. claim 1 4. An autoadjusting electron microscope according to  claim 1 , wherein the image processor derives the third image from the first and the second by claim 1 frequency-transforming the first image and the second image to produce a frequency-transformed first image and a frequency-transformed second image,  combining the frequency-transformed first image and the frequency-transformed second image to produce a combined image, and  frequency-transforming or inverse frequency-transforming the combined image to obtain the third image. 5. An autoadjusting electron microscope comprising: an electron gun for emitting a first electron beam;  a deflector for deflecting the first electron beam emitted from the electron gun;  a specimen stage for holding a specimen and moving the specimen relative to the first electron beam;  an electron lens for irradiating the specimen with the first electron beam deflected by the deflector;  a detector for detecting a second electron beam generated by irradiation of the specimen with the first electron beam;  a storage for storing two images obtained by the detector at respective times separated by a predetermined interval of time;  an image processor for forming a third image by performing an orthogonal transformation or an inverse orthogonal transformation on the two images; and  a controller for determining a speed at which the specimen is being moved relative to the first electron beam by the specimen stage based on a peak appearing in the third image, and generating control signals for the deflector based on the determined speed. 6. An autoadjusting electron microscope comprising: a source of electrons for emitting an electron beam;  a lens for collimating the electron beam emitted from the source of electrons to produce a collimated electron beam and irradiating a specimen with the collimated electron beam;  a specimen stage for holding the specimen and moving the specimen relative to the lens;  a camera for detecting a transmission electron microscope (TEM) image of the specimen produced by irradiation of the specimen with the collimated electron beam;  a deflector for shifting a position of the TEM image of the specimen to be detected by the camera;  a storage for storing a first TEM image detected by the camera at a first moment of time and a second TEM image detected by the camera at a second moment of time different from the first moment of time;  an image processor for determining an amount of displacement between the first TEM image and the second TEM image based on a peak occurring in an analysis image derived from the first TEM image and the second TEM image by  Fourier-transforming the first TEM image and the second TEM image to produce a Fourier-transformed first TEM image and a Fourier-transformed second TEM image,  synthesizing the Fourier-transformed first TEM image and the Fourier-transformed second TEM image to produce a synthesized image, and  Fourier-transforming or inverse Fourier-transforming the synthesized image to obtain the analysis image; and  a controller for controlling the deflector based on the displacement determined by the image processor to prevent the position of the TEM image of the specimen to be detected by the camera from moving relative to the lens when the specimen stage moves the specimen relative to the lens. 7. An autoadjusting electron microscope comprising: a specimen stage for holding a specimen;  an electron gun for emitting a first electron beam;  an electron lens for irradiating the specimen with the first electron beam;  a deflector for deflecting the first electron beam such that an incident angle at which the first electron beam is incident on the specimen changes from a first incident angle to a second incident angle;  a detector for detecting a second electron beam generated by irradiation of the specimen with the first electron beam;  a storage for storing a first image obtained by the detector when the first electron beam is incident on the specimen at the first incident angle and a second image obtained by the detector when the first electron beam is incident on the specimen at the second incident angle;  an image processor for deriving a third image constituting an analysis image from the first image and the second image by  Fourier-transforming the first image and the second image to produce a Fourier-transformed first image and a Fourier-transformed second image,  computing a phase variant image from the Fourier-transformed first image and the Fourier-transformed second image, and  Fourier-transforming or inverse Fourier-transforming the phase variant image to obtain the third image;  a computer for determining an amount of displacement between the first image and the second image based on a peak appearing in the third image;  an identifier for determining whether a consistency between the first image and the second image is within a predetermined range based on a magnitude of the peak appearing in the third image; and  a transformer for transforming results obtained by the computer and the identifier into an amount of defocus of the electron lens relative to the specimen. 8. An autoadjusting electron microscope according to  claim 7 , wherein at least two peaks appear in the third image; and claim 7 wherein the autoadjusting electron microscope further comprises a selector for selecting one of the at least two peaks appearing in the third image based on an occurrence of a peak at a location in the third image corresponding to a situation where the first image matches the second image. 9. An autoadjusting electron microscope according to  claim 7 , wherein the computer determines the amount of displacement between the first image and the second image to a precision of less than one pixel of the first image and the second image. claim 7 10. An autoadjusting electron microscope comprising: an electron gun for emitting a first electron beam;  a deflector for deflecting the first electron beam emitted from the electron gun;  a specimen stage for holding a specimen and moving the specimen relative to the first electron beam;  an electron lens for irradiating the specimen with the first electron beam deflected by the deflector;  a detector for detecting a second electron beam generated by irradiation of the specimen with the first electron beam;  a storage for storing two images obtained by the detector at respective times separated by a predetermined interval of time;  an image processor for forming a third image by performing an orthogonal transformation or an inverse orthogonal transformation on the two images;  a controller for determining a speed at which the specimen is being moved relative to the first electron beam by the specimen stage based on a peak appearing in the third image, and generating control signals for the deflector based on the determined speed; and  an identifier for determining whether to supply the control signals to the deflector based on a magnitude of the peak appearing in the third image. 11. An autoadjusting electron microscope comprising: a source of electrons for emitting an electron beam;  a lens for collimating the electron beam emitted from the source of electrons to produce a collimated electron beam and irradiating a specimen with the collimated electron beam;  a specimen stage for holding the specimen and moving the specimen relative to the lens;  a camera for detecting a transmission electron microscope (TEM) image of the specimen produced by irradiation of the specimen with the collimated electron beam;  a deflector for shifting a position of the TEM image of the specimen to be detected by the camera;  a storage for storing a first TEM image detected by the camera at a first moment of time and a second TEM image detected by the camera at a second moment of time different from the first moment of time;  an image processor for determining an amount of displacement between the first TEM image and the second TEM image based on a peak occurring in an analysis image derived from the first TEM image and the second TEM image by  Fourier-transforming the first TEM image and the second TEM image to produce a Fourier-transformed first TEM image and a Fourier-transformed second TEM image,  computing a phase variant image from the Fourier-transformed first TEM image and the Fourier-transformed second TEM image, and  Fourier-transforming or inverse Fourier-transforming the phase variant image to obtain the analysis image; and  a controller for controlling the deflector based on the displacement determined by the image processor to prevent the position of the TEM image of the specimen to be detected by the camera from moving relative to the lens when the specimen stage moves the specimen relative to the lens.