Patent Number: 
Section: claims

1. An inspection apparatus for inspecting a wafer through imaging, the inspection apparatus comprising:an electron optical system configured to radiate an electron beam on a certain area of a wafer corresponding to an inspection region of the wafer, the electron optical system including a time delay integration (TDI) sensor, an image processor, a controller, and a wafer stage configured to move the wafer at a set speed, the TDI sensor being configured to detect an image of the wafer upon radiation of the electron beam on the certain area of the wafer and transmit the image as image signals to the image processor, the image processor being configured to receive the image signals, perform an inspection of the inspection region based on the image signals, and output a result of the inspection, the controller being configured to control operations of the electron beam, the TDI sensor, the image processor, and the wafer stage according to a set of conditions; anda display device coupled to the electron optical system and configured to display an indication of the result of the inspection output by the image processor, andwherein the controller is configured to implement a graphical user interface (GUI) that includes a graph element displayed via the display device, the graph element displaying a respective relationship among values of S and D for each of a plurality of values of P on a graph with respect to a specified value of L by assuming D and S as coordinates axes, where each of value of S defines an area of the wafer to be inspected per unit time, each value of D defines a width in a moving direction of the wafer that corresponds to a unit pixel of the image, each value of P defines an image signal acquisition frequency for image signal acquisition cycles, and each value of L defines a length in a direction perpendicular to the moving direction of the wafer for which image data is obtained in each image signal acquisition cycle in a range of an inspection image in the region on which the electron beam is radiated, such that a formula S=D×L×P is satisfied for the respective relationships displayed on the graph,wherein the GUI includes a pointer element displayed on the display screen and accessible by a user such that the user can move the pointer within the graph and select a position on the graph,wherein the graph element is implemented to display the values of D and S for each position of the pointer within the graph according to the specified value of L;wherein the controller is configured to control the electron optical system according to the values of D and S for the position on the graph selected by the user, andwherein the controller is configured to disregard the values for S, L, D, and P that are selected upon the pointer being positioned on the graph when at least one of the values is out of a range in which the apparatus is configured to operate. 2. The apparatus, according to claim 1, wherein the electron beam is a planar electron beam. 3. The apparatus, according to claim 1, wherein the electron optical system is a projection optical system in which the TDI sensor is configured to obtain the image signals to transmit by projecting the inspection region of the image during detection. 4. The apparatus, according to claim 1, wherein the graph element is displayed with a plurality of lines in the graph that each correspond to a respective value of P with respect to a set value of L. 5. The apparatus, according to claim 4, wherein the GUI is implemented to permit the user to specify the value of L, and wherein the graph element is implemented such that the graph is changed corresponding to the value of L specified by the user in accordance with the formula of S=D×L×P. 6. The apparatus, according to claim 1, wherein the GUI is implemented such that a maximum value of L that can be specified is 200 microns. 7. The apparatus, according to claim 1, wherein the values of D corresponding to positions on the graph are within a range between 0 nm and 250 nm. 8. The apparatus, according to claim 1, wherein the controller holds a numerical table in which a plurality of sets of conditions for operating the electron optical system each corresponding to a respective pair of D and L values are set beforehand and determines a set of conditions for operating the electron lens according to values of D and L specified by the user via the GUI with reference to the numerical table. 9. An inspection apparatus for inspecting a wafer through imaging, the inspection apparatus comprising:an electron optical system configured to radiate an electron beam on a certain area of a wafer corresponding to an inspection region of the wafer, the electron optical system including a time delay integration (TDI) sensor, an image processor, a controller, and a wafer stage configured to move the wafer at a set speed, the TDI sensor being configured to detect an image of the wafer upon radiation of the electron beam on the certain area of the wafer and transmit the image as image signals to the image processor, the image processor being configured to receive the image signals, perform an inspection of the inspection region based on the image signals, and output a result of the inspection, the controller being configured to control operations of the electron beam, the TDI sensor, the image processor, and the wafer stage according to a set of conditions; anda display device coupled to the electron optical system and configured to display an indication of the result of the inspection output by the image processor, andwherein the controller is configured to implement a graphical user interface (GUI) that includes a graph element displayed via the display device, the graph element displaying a graph related to a time delay integration formula S=D×L×P with respect to a plurality of values of P and a specified value of L by assuming D and S as coordinates axes, where each of value of S defines an area of the wafer to be inspected per unit time, each value of D defines a width of the wafer in a direction image in the region on which the electron beam is irradiated in each image acquisition cycle that corresponds to a unit pixel of the image, each value of P defines an image signal acquisition frequency for image signal acquisition cycles, and each value of L defines a length in the direction image in the region on which the electron beam is radiated in each image acquisition cycle,wherein the coordinate axis is S or S′ defined as a number of wafers to be processed per hour, an inverse number to define a processing time of one wafer or a time required for a unit area inspection by calculating S, andwherein the GUI includes a pointer element displayed on the display screen and accessible by a user such that a user can move the pointer within the graph and select a position on the graph,wherein the graph element is implemented to display the values of D and S or S′ for each position of the pointer within the graph according to the specified value of L;wherein the controller is configured to control the electron optical system according to the values of D and S or S′ for the position on the graph selected by the user, andwherein the controller is configured to disregard the values for S, L, D, and P that are selected upon the pointer being positioned on the graph when at least one of the values is out of a range in which the apparatus is configured to operate. 10. The apparatus, according to claim 9, wherein the electron beam is a planar electron beam. 11. The apparatus, according to claim 9, wherein the electron optical system is a projection optical system in which the TDI sensor is configured to obtain the image signals to transmit by projecting the inspection region of the image during detection. 12. The apparatus, according to claim 9, wherein the graph element is displayed with a plurality of lines in the graph that each correspond to a respective value of P with respect to a set value of L. 13. The apparatus, according to claim 12, wherein the GUI is implemented to permit the user to specify the value of L, and wherein the graph element is implemented such that the graph is changed corresponding to the value of L specified by the user in accordance with the formula of S=D×L×P. 14. The apparatus, according to claim 9, wherein the GUI is implemented such that a maximum value of L that can be specified is 200 microns. 15. The apparatus, according to claim 9, wherein the values of D corresponding to positions on the graph are within a range between 0 nm and 250 nm. 16. The apparatus, according to claim 9, wherein the controller holds a numerical table in which a plurality of sets of conditions for operating the electron optical system each corresponding to a respective pair of D and L values are set beforehand and determines a set of conditions for operating the electron lens according to values of D and L specified by the user via the GUI with reference to the numerical table.