Abstract: Smart glasses and position adjusting end piece thereof are provided. The smart glasses include: a wearing body provided with a connecting wire, wherein two ends of the connecting wire extend out of two sides of the wearing body respectively; position adjusting end pieces installed on the two sides of the wearing body, which can be rotated around a first direction relative to the wearing body within a first angle range and maintained at any position within the first angle range, and further can be rotated around a second direction relative to the wearing body within a second angle range and maintained at any position within the second angle range; and hinges installed on an end of the position adjusting end pieces away from the wearing body and are electrically connected to the connecting wire. The smart glasses can fine-tune the shape and adjust the size of the whole smart glasses.

Abstract: From only a single two-dimensional source image (20) of a scene, multiple images (28) of the scene are generated, wherein each image is from a different viewing direction or angle. For each of the multiple images, a disparity is generated corresponding to the viewing direction and combined with significant pixels (e.g., edge detected pixels) in the source image. The disparity may be filtered (26) (e.g., low-pass filtered) prior to combined with the significant pixels. The multiple images are combined into an integrated image for display, for example, on an auto stereoscopic monitor (10). The process can be repeated on multiple related source images to create a video sequence.

Abstract: Fast processing of information represented in digital holograms is provided to facilitate generating a hologram for displaying three-dimensional (3-D) holographic images representative of a 3-D object scene on a display device. A holographic generator component (HGC) can receive or generate visual images, comprising depth and parallax information, of a 3-D object scene. A hologram processor component can apply a first non-uniform transform to a visual image to generate a first signal, and can apply a second transform to the first signal to generate a second signal that corresponds to a hologram that represents the 3-D object scene. The hologram can be illuminated with a light beam to facilitate generating a holographic image(s) that can be a reconstructed image that reconstructs the 3-D object scene. A display component can display the holographic image(s) for viewing by an observer.

Abstract: Fast processing of information represented in digital holograms is provided to facilitate converting a complex Fresnel hologram into a phase-only hologram, which can be a localized error diffusion and redistribution (LERDR) hologram, for displaying 3-D holographic images representative of a 3-D object scene. For a complex Fresnel hologram representing a 3-D object scene, a holographic generator component (HGC) can directly apply an LERDR process to the complex hologram to facilitate converting the complex hologram into an LERDR hologram. As part of the LERDR process, the HGC can partition the complex hologram into segments, convert the complex values of the pixels in each segment to phase-only values, and apply error diffusion to each segment to facilitate generating the phase-only hologram. The HGC can apply error redistribution to the last pixel of each segment to produce the resulting LERDR hologram, which can be displayed on a phase-only display device.

Abstract: Cryptographic techniques for encrypting images, and decrypting and reconstructing images, are provided to facilitate preventing unauthorized access to images. A holographic cryptographic component (HCC) generates complex holograms of multi-dimensional source images of a multi-dimensional object scene. The HCC generates phase holograms, based on the complex holograms, using a stochastic hologram generation process, and encrypts the phase holograms to generate encrypted holograms based on a random phase mask, which can be the private encryption key. At the decoding end, an HCC overlays a conjugate phase mask on the encrypted holograms to decrypt them, wherein the decrypted holograms are illuminated with a coherent light source to generate holographic images that reconstruct the source images. The source images are only reconstructed properly if the correct phase mask is used. If HCC applies the encryption process repetitively to the same source image, HCC can generate a different encrypted hologram in each run.

Abstract: Cryptographic techniques for encrypting images, and decrypting and reconstructing images, are provided to facilitate preventing unauthorized access to images. A holographic cryptographic component (HCC) can generate a global image comprising a scaled version of a source image and random content, generate a phase hologram representing the global image, and encrypt the phase hologram to generate an encrypted hologram based on a random phase mask, which can be the private encryption key. To reconstruct the source image, an HCC can overlay a phase mask, which can be a conjugate of the random phase mask, on the encrypted hologram to decrypt it, and can illuminate the decrypted hologram with a coherent light source. The source image is only reconstructed properly if the correct phase mask is used. If HCC applies the encryption process repetitively to the same source image, HCC can generate a different encrypted hologram in each run.

Abstract: The disclosed subject matter relates to an architecture that can facilitate generation of enhanced spatial effects for stereo audio systems. Such can be accomplished by integrating on top ambience signal boosting employed in conventional systems. In particular, the ambience signal can be transformed according to a time-dependent function, which can simulate the auditory impressions of a real-world listening environment that may contain static, regularly moving, and/or irregular moving elements.

Abstract: Cryptographic techniques for encrypting images, and decrypting and reconstructing images, are provided to facilitate preventing unauthorized access to images. A holographic cryptographic component (HCC) generates complex holograms of multi-dimensional source images of a multi-dimensional object scene. The HCC generates phase holograms, based on the complex holograms, using a stochastic hologram generation process, and encrypts the phase holograms to generate encrypted holograms based on a random phase mask, which can be the private encryption key. At the decoding end, an HCC overlays a conjugate phase mask on the encrypted holograms to decrypt them, wherein the decrypted holograms are illuminated with a coherent light source to generate holographic images that reconstruct the source images. The source images are only reconstructed properly if the correct phase mask is used. If HCC applies the encryption process repetitively to the same source image, HCC can generate a different encrypted hologram in each run.

Abstract: Neural control of holograms is provided to facilitate improving the viewing pleasure of a viewer. A holographic processor component can generate holograms representing a multi-dimensional object scene. A sensor component can detect brain waves of the viewer at different frequency bands. The holographic processor component can analyze the brain waves at difference frequency bands to determine respective strengths of the brain waves at different frequency bands. The holographic processor component can determine an adjustment(s) to be made to a parameter(s) of an optical setting associated with the holograms based on the respective strengths of the brain waves at different frequency bands. The holographic processor component can adjust the optical setting for the holograms based on the parameter adjustment(s) to facilitate generating and displaying holograms that have been modified in response to the detected brain waves at different frequency bands to facilitate customizing the holograms for the viewer.

Abstract: Fast processing of information represented in digital holograms is provided to facilitate generating a hologram for displaying three-dimensional (3-D) holographic images representative of a 3-D object scene on a display device. A holographic generator component (HGC) can receive or generate visual images, comprising depth and parallax information, of a 3-D object scene. A hologram processor component can apply a first non-uniform transform to a visual image to generate a first signal, and can apply a second transform to the first signal to generate a second signal that corresponds to a hologram that represents the 3-D object scene. The hologram can be illuminated with a light beam to facilitate generating a holographic image(s) that can be a reconstructed image that reconstructs the 3-D object scene. A display component can display the holographic image(s) for viewing by an observer.

Abstract: Fast processing of information represented in digital holograms is provided to facilitate generating a phase-only hologram for displaying 3-D holographic images representative of a 3-D object scene on a display device. A holographic generator component (HGC) can receive or generate visual images, comprising depth and parallax information, of a 3-D object scene. A hologram processor component can downsample an intensity image of a visual image of the 3-D object scene using a uniform or random lattice to facilitate converting the intensity image to a sparse image. The hologram processor component can generate a complex 3-D Fresnel hologram, comprising the depth and parallax information, based on the sparse image using a fast hologram generation algorithm. The hologram processor component modify the magnitude of the pixels of the complex hologram to a defined homogeneous value to facilitate converting the complex hologram to a phase-only hologram.

Abstract: Fast processing of information represented in digital holograms is provided to facilitate converting a complex Fresnel hologram into a single phase-only hologram, which can be called a bidirectional error diffusion (BERD) hologram, for displaying 3-D holographic images representative of a 3-D object scene on a display device. The BERD hologram can be capable of representing a 3-D object scene and preserving favorable visual quality on the reconstructed holographic image. A holographic generator component (HGC) can receive or generate a complex Fresnel hologram representing a 3-D object scene. The HGC can directly apply the BERD process to the complex Fresnel hologram to facilitate converting the complex Fresnel hologram into a phase-only hologram. Alternatively, the HGC can directly apply a unidirectional error diffusion process to the complex Fresnel hologram to facilitate converting the complex Fresnel hologram into a phase-only hologram.

Abstract: Neural induced enhancement of audio signals is provided to facilitate improving the listening pleasure of a user. An audio processor component can detect brain waves of a user at different frequency bands, analyze the brain wave signal in each of the different frequency bands, and can adjust one or more audio enhancement effects based at least in part on the results of the analysis. The audio processor component can adjust a spatial effect of audio signals, integrate a periodic or random variation on a spatial widening effect of audio signals, adjust a spatial effect of delayed audio signals, integrate a periodic or random variation on a spatial widening effect of the delayed audio signals, or adjust another audio enhancement effect(s) based at least in part on the analysis results, comprising information relating to the respective strengths of the one or more different frequency bands of the brain waves.

Abstract: Techniques for efficiently generating full parallax 3-D holographic images of a 3-D real or synthetic object scene are presented. A holographic generator component (HGC) can receive a real object scene or generate a synthetic object scene. The HGC can downsample the scene by a defined downsampling factor and generate, from the downsampled scene, an intermediate object wavefront recording plane (WRP) that can be placed in close proximity to the scene. The HGC can expand and interpolate the WRP to generate the holographic images. The HGC can decompose a scene into polyphase image components (PICs), generate a WRP for the image components, sum the WRP of the PICs, and expand and interpolate the WRP to generate holographic images of the scene. The HGC can utilize look-up tables to store and use wavefront patterns of each region of an image to facilitate reducing computational operations in generating the holographic images.

Abstract: Cryptographic techniques for encrypting images, and decrypting and reconstructing images, are provided to facilitate preventing unauthorized access to images. A holographic cryptographic component (HCC) can generate a global image comprising a scaled version of a source image and random content, generate a phase hologram representing the global image, and encrypt the phase hologram to generate an encrypted hologram based on a random phase mask, which can be the private encryption key. To reconstruct the source image, an HCC can overlay a phase mask, which can be a conjugate of the random phase mask, on the encrypted hologram to decrypt it, and can illuminate the decrypted hologram with a coherent light source. The source image is only reconstructed properly if the correct phase mask is used. If HCC applies the encryption process repetitively to the same source image, HCC can generate a different encrypted hologram in each run.

Abstract: Neural control of holograms is provided to facilitate improving the viewing pleasure of a viewer. A holographic processor component can generate holograms representing a multi-dimensional object scene. A sensor component can detect brain waves of the viewer at different frequency bands. The holographic processor component can analyze the brain waves at difference frequency bands to determine respective strengths of the brain waves at different frequency bands. The holographic processor component can determine an adjustment(s) to be made to a parameter(s) of an optical setting associated with the holograms based on the respective strengths of the brain waves at different frequency bands. The holographic processor component can adjust the optical setting for the holograms based on the parameter adjustment(s) to facilitate generating and displaying holograms that have been modified in response to the detected brain waves at different frequency bands to facilitate customizing the holograms for the viewer.

Abstract: Techniques for charging electronic devices are presented. A charger controller component controls supplying power to an electronic device having a solar cell component using optical charging. The charger controller component detects a shape and position of the electronic device located on a charger substrate component. The charger controller component identifies a subset of a plurality of light sources associated with the charger substrate component that correspond to the shape and position of the electronic device, and controls illumination of the light sources to illuminate the subset of light sources. The illumination of the subset of light sources provides optical waves to the electronic device that are converted to electrical energy to charge a power component of the electronic device. An optical processing element can employ an array of lenticular lens or microlens that can expand coverage of each light source and enhance uniformity of the illuminated area.

Abstract: Techniques for controlling switching of a barrier component for efficiently displaying various types of 2-D content and 3-D content on a projector screen are presented. A barrier control component detects an optical signal in a control region of the projector screen that is providing visual content to the barrier component, and identifies the type of visual content, such as 2-D content or 3-D autostereoscopic content, based on the optical signal. The barrier control component identifies a control signal based on the identified content type, and transmits the control signal to the barrier component via a wireline or wireless connection. The barrier component is controlled to automatically switch to a desired mode, such as 2-D mode or 3-D autostereoscopic mode, and employ a desired barrier pattern, in response to the received control signal. The barrier component is powered using a solar cell component that generates power using the optical signal.

Abstract: Techniques for presenting content provided by a mobile device on a second communication device are presented. A content enhancer component (CEC) connects via a wired or wireless communication connection to the second communication device to communicate content to the second communication device, which has a larger display than or superior audio to the mobile device. The CEC captures content and interaction between the user and mobile device in a capture region of the CEC. The CEC reconstructs the content and the user-related interaction for presentation on the second communication device. The second communication device can have a 2-D or 3-D display. If a 3-D display, the CEC can convert captured video content into a 3-D format to provide 3-D perception when content is displayed on the second communication device. The captured audio signal can be processed to provide an enhanced stereo or 3-D sound effect.

Abstract: Techniques for generating 3-D holographic images of a 3-D real or synthetic object scene are presented. A holographic generator component (HGC) can obtain a real or synthetic 3-D object scene. The HGC generates a high-resolution grating, and generates a low-resolution mask based on the 3-D object scene. The HGC overlays the mask on the grating to generate the hologram, which can be a digital mask programmable hologram. The HGC can use the grating as an encryption key, if desired, wherein the mask can be encrypted based on the encryption key. The display component receives the hologram and can generate holographic images, based on the hologram, and display the holographic images using one or more low-resolution displays. The grating and display can be arranged in various formations in relation to each other. A single display can be partitioned into a tile structure for displaying holographic images in the respective tiles.