Systems, devices, and methods for spatially-multiplexed holographic optical elements

1 . A spatially-multiplexed holographic optical element (“HOE”) for use in a display having multiple exit pupils, wherein the spatially-multiplexed HOE includes at least one layer of holographic material and that at least one layer of holographic material comprises: a first holographic region to receive light from a light source, apply a first optical function thereto, and direct the light towards a first exit pupil with the first optical function applied thereto; and a second holographic region to receive light from the light source, apply a second optical function thereto, and direct the light towards a second exit pupil with the second optical function applied thereto, wherein: the second holographic region is spatially-separated from the first holographic region; and the second exit pupil is spatially-separated from the first exit pupil. 2 . The spatially-multiplexed HOE of claim 1 wherein the first optical function converges the light towards the first exit pupil and the second optical function converges the light towards the second exit pupil. 3 . The spatially-multiplexed HOE of claim 2 wherein the first optical function converges the light towards the first exit pupil with a first rate of convergence and the second optical function converges the light towards the second exit pupil with a second rate of convergence, the second rate of convergence different from the first rate of convergence. 4 . The spatially-multiplexed HOE of claim 1 wherein both the first optical function and the second optical function reflect the light from the light source. 5 . The spatially-multiplexed HOE of claim 1 wherein the first optical function converges the light towards the first exit pupil and the second optical function diverges the light towards the second exit pupil. 6 . The spatially-multiplexed HOE of claim 1 wherein the first holographic region includes a first hologram and the second holographic region includes a second hologram. 7 . The spatially-multiplexed HOE of claim 6 wherein the at least one layer of holographic material comprises a first continuous piece of holographic material that includes both the first holographic region and the second holographic region, and wherein the first hologram is in the first holographic region of the first continuous piece of holographic material and the second hologram is in the second holographic region of the first continuous piece of holographic material. 8 . The spatially-multiplexed HOE of claim 6 wherein the at least one layer of holographic material comprises: a first piece of holographic material that includes the first holographic region and wherein the first hologram is in the first holographic region of the first piece of holographic material; and a second piece of holographic material that includes the second holographic region and wherein the second hologram is in the second holographic region of the second piece of holographic material. 9 . The spatially-multiplexed HOE of claim 8 , further comprising a substrate layer that carries both the first piece of holographic material and the second piece of holographic material. 10 . The spatially-multiplexed HOE of claim 1 wherein the at least one layer of holographic material includes a holographic material selected from a group consisting of: a holographic film, a silver halide compound, and a photopolymer. 11 . The spatially-multiplexed HOE of claim 1 wherein the at least one layer of holographic material further comprises: at least one additional holographic region to receive light from the light source, each additional holographic region to apply a respective optical function to light received from the light source and direct the light towards a respective exit pupil, wherein: each additional holographic region is spatially-separated from the other holographic regions; and each exit pupil is spatially-separated from the other exit pupils. 12 . The spatially-multiplexed HOE of claim 1 wherein the first holographic region and the second holographic region are both substantially transparent to visible light having a wavelength that is not a wavelength of light provided by the light source. 13 . A wearable heads-up display (“WHUD”) comprising: a support structure that in use is worn on a head of a user; a scanning laser projector carried by the support structure; and a spatially-multiplexed holographic combiner carried by the support structure, wherein the spatially-multiplexed holographic combiner is positioned within a field of view of an eye of the user when the support structure is worn on the head of the user, and wherein the spatially-multiplexed holographic combiner comprises at least one layer of holographic material, the at least one layer of holographic material including: a first holographic region positioned and oriented to receive a first range of light signals from the scanning laser projector and to converge the first range of light signals to a first exit pupil at or proximate the eye of the user; and a second holographic region positioned and oriented to receive a second range of light signals from the scanning laser projector and to converge the second range of light signals to a second exit pupil at or proximate the eye of the user, wherein the second holographic region is spatially-separated from the first holographic region at the spatially-multiplexed holographic combiner and the second exit pupil is spatially-separated from the first exit pupil at the eye of the user. 14 . The WHUD of claim 13 wherein the support structure has a general shape and appearance of an eyeglasses frame, and wherein the spatially-multiplexed holographic combiner further comprises an eyeglass lens that carries the at least one layer of holographic material. 15 . The WHUD of claim 13 wherein the first holographic region of the spatially-multiplexed holographic combiner includes a first hologram and the second holographic region of the spatially-multiplexed holographic combiner includes a second hologram. 16 . The WHUD of claim 15 wherein the at least one layer of holographic material in the spatially-multiplexed holographic combiner comprises a first continuous piece of holographic material that includes both the first holographic region and the second holographic region, and wherein the first hologram is in the first holographic region of the first continuous piece of holographic material and the second hologram is in the second holographic region of the first continuous piece of holographic material. 17 . The WHUD of claim 15 wherein the at least one layer of holographic material in the spatially-multiplexed holographic combiner comprises: a first piece of holographic material that includes the first holographic region, wherein the first hologram is in the first holographic region of the first piece of holographic material; and a second piece of holographic material that includes the second holographic region, wherein the second hologram is in the second holographic region of the second piece of holographic material. 18 . The WHUD of claim 13 wherein the at least one layer of holographic material in the spatially-multiplexed holographic combiner further includes: at least one additional holographic region, each additional holographic region positioned and oriented to receive a respective range of light signals from the scanning laser projector and to converge the respective range of light signals to a respective exit pupil at or proximate the eye of the user, wherein each additional holographic region is spatially-separa