Display apparatus providing expanded eye box

What is claimed is: 1 . A display apparatus comprising: a processor; an image generator comprising: a plurality of spatially separated light sources configured such that light beams emitted from the plurality of spatially separated light sources propagate along different paths; and a spatial light modulator configured to generate images using light from at least one of the plurality of spatially separated light sources; a holographic optical element configured, for each of the generated images that is incident on the holographic optical element, output a plurality of images corresponding to each of the generated images at spatially different points by focusing each of the generated images on the spatially different points; an image deflector provided in an optical path between the image generator and the holographic optical element, and configured to deflect each of the generated images received from the image generator to the holographic optical element; and an eye tracking sensor configured to track a user's gaze, wherein: the holographic optical element is biaxially driven to adjust a deflection direction of the image deflector, for each of the generated images that is incident on the holographic optical element in an adjusted deflection direction, the holographic optical element focuses the plurality of images two-dimensionally onto a same focal plane while simultaneously adjusting positions of each of the plurality of images according to the adjusted deflection direction and adjusting a center of the plurality of images according to the adjusted deflection direction, and while the positions of each of the plurality of images are simultaneously adjusted, a distance between the plurality of images is maintained to be greater than or equal to a predetermined pupil size and less than or equal to three times the predetermined pupil size, and a distance between the center of the plurality of images before and after an adjustment of the positions of each of the plurality of images, is made greater than or equal to the predetermined pupil size, and wherein the processor is configured to selectively activate one or more of the plurality of spatially separated light sources based on the on tracking results received from the eye tracking sensor and to control a modulation signal applied to the spatial light modulator in synchronization with the selectively activated one or more light sources, such that the images generated by the spatial light modulator are projected in different directions and are incident on the holographic optical element from different angles. 2 . The display apparatus of claim 1 , wherein the generated images and the plurality of images have substantially identical optical characteristics. 3 . The display apparatus of claim 1 , wherein the holographic optical element is configured such that: when each of the generated images is incident on the holographic optical element in a first direction, the holographic optical element focuses the plurality of images such that the center of the plurality of images is at a first position; and when each of the generated images is incident on the holographic optical element in a second direction that is different from the first direction, the holographic optical element focuses the plurality of images such that the center of the plurality of images is at a second position that is different from the first position. 4 . The display apparatus of claim 3 , wherein the first position and the second position are located on an identical focal plane. 5 . The display apparatus of claim 3 , wherein a distance between the first position and the second position is greater than or equal to a user's pupil size. 6 . The display apparatus of claim 1 , further comprising an optical system comprising one or more lenses, wherein the optical system is provided between the image generator and the image deflector and configured to cause all light included in the generated images output from the image generator to be incident on the image deflector. 7 . The display apparatus of claim 1 , wherein the holographic optical element comprises: a first surface on which generated images are incident and from which the plurality of images are output; and a second surface which is opposite to the first surface and on which external light corresponding to an external environment is incident. 8 . The display apparatus of claim 1 , wherein the image generator is integrated with the image deflector. 9 . The display apparatus of claim 1 , wherein the holographic optical element comprises: a reflective surface configured to output the plurality of images when the generated images are incident from the image deflector; a frame that supports the reflective surface; a first supporting structure positioned between the frame and a first corner of the holographic optical element, to pivotally support the first corner of the holographic optical element; and a second supporting structure positioned between the frame and a second corner of the holographic optical element, to elastically support the second corner of the holographic optical element, wherein the first corner and the second corner are located diagonally across from each other on the reflective surface. 10 . The display apparatus of claim 1 , wherein the processor is further configured to apply a distortion compensation algorithm to image information, which is used by the image generator to generate the plurality of images, to compensate for image shape distortion caused by a biaxial drive mechanism. 11 . The display apparatus of claim 10 , wherein the distortion compensation algorithm is performed by inversely transforming a mapping algorithm that maps pixel position information included in the image information to pixel position information included in the plurality of images focused by the holographic optical element. 12 . The display apparatus of claim 10 , wherein the processor is further configured to periodically vary the deflection direction with time by controlling at least one of the image generator, the image deflector, and the holographic optical element. 13 . The display apparatus of claim 1 , wherein the holographic optical element comprises: a reflective surface configured to output the plurality of images when the generated images are incident from the image deflector; and a pair of actuators positioned at two diagonally opposite corners of the reflective surface and configured to move the two diagonally opposite corners to adjust a surface geometry of the reflective surface. 14 . A method of controlling a display apparatus, the method comprising: receiving a result of tracking a user's gaze from an eye-tracking sensor emitting light from a plurality of spatially separated light sources to propagate along different paths; generating images by controlling the plurality of spatially separated light sources configured such that light beams emitted from the plurality of spatially separated light sources propagate along different paths, and controlling a spatial light modulator configured to generate the images using light from at least one of the plurality of spatially separated light sources, wherein the generating of the image comprises: selectively activating one or more of the plurality of spatially separated light sources based on the result of tracking the user's gaze and controlling a modulation signal applied to the spatial light modulator in synchronization with the selectively activated one or more light sources, such that the images generated by the spatial light modulator are projected in diffe