An image sensor bridge interface is provided. The interface is situated between an image sensor and a processor. The interface comprises an integrated circuit. The integrated circuit comprises a Field-Programmable Gate Array (FPGA) decoupled from both image signals provided from the image sensor and a processor connected to the integrated circuit. The FPGA separates Ultraviolet (UV) and Infrared (IR) data values from image sensor-provided image data and embeds the UV and IR data values within the horizontal blanking, vertical blanking, and/or active video components of a video feed. The video feed provided from the integrated circuit to the processor using a standard video interface, and the processor providing the video feed or providing UV images, IR images, and Red, Green, and Blue (RGB) images separated from the video feed to a computing core of a host device.

An image sensor bridge interface is provided. The interface is situated between an image sensor and a processor. The interface comprises an integrated circuit. The integrated circuit comprises a Field-Programmable Gate Array (FPGA) decoupled from both image signals provided from the image sensor and a processor connected to the integrated circuit. The FPGA separates Ultraviolet (UV) and Infrared (IR) data values from image sensor-provided image data and embeds the UV and IR data values within the horizontal blanking, vertical blanking, and/or active video components of a video feed. The video feed provided from the integrated circuit to the processor using a standard video interface, and the processor providing the video feed or providing UV images, IR images, and Red, Green, and Blue (RGB) images separated from the video feed to a computing core of a host device.

An image sensor bridge interface is provided. The interface is situated between an image sensor and a processor. The interface comprises an integrated circuit. The integrated circuit comprises a Field-Programmable Gate Array (FPGA) decoupled from both image signals provided from the image sensor and a processor connected to the integrated circuit. The FPGA separates Ultraviolet (UV) and Infrared (IR) data values from image sensor-provided image data and embeds the UV and IR data values within the horizontal blanking, vertical blanking, and/or active video components of a video feed. The video feed provided from the integrated circuit to the processor using a standard video interface, and the processor providing the video feed or providing UV images, IR images, and Red, Green, and Blue (RGB) images separated from the video feed to a computing core of a host device.

A control device includes: generation circuitry configured to output a field signal to a medical imaging device; first detection circuitry configured to detect a horizontal synchronization signal from video data output from the medical imaging device, the video data including at least the horizontal synchronization signal; and a monitoring circuitry configured to monitor whether or not an abnormality occurs in one frame period of the video data based on a period of the horizontal synchronization signal detected by the first detection circuitry for a predetermined n-th time after polarity of the field signal is switched.

A method for receiving a broadcast signal includes receiving the broadcast signal including a signal frame; demodulating the received broadcast signal by an OFDM (Orthogonal Frequency Division Multiplex) scheme; frame parsing the signal frame carrying broadcast data, signaling table for a service, the broadcast data and the signaling table is transmitted through a broadcast network, the signaling table including a service identifier identifying the broadcast service, category information indicating a category of the broadcast service and bootstrapping information to obtain a service signaling information for the broadcast service, the service signaling information is transmitted via either the broadcast network or a broadband network that is different from the broadcast network; time de-interleaving the signal frame; parsing the signaling table to acquire the service signaling information, the service signaling information is acquired via: the broadband network based on a bootstrapping information that includes URL (Uniform Resource Locator) information of the service signaling information, or the broadcast network based on a bootstrapping information that includes an IP (Internet Protocol) address of an IP packet carrying the service signaling information; and parsing the service signaling information including transport session information for one or more transport packets carrying one or more SGDDs (Service Guide Delivery Descriptors).

A method for receiving a broadcast signal includes receiving the broadcast signal including a signal frame; demodulating the received broadcast signal by an OFDM (Orthogonal Frequency Division Multiplex) scheme; frame parsing the signal frame carrying broadcast data, signaling table for a service, the broadcast data and the signaling table is transmitted through a broadcast network, the signaling table including a service identifier identifying the broadcast service, category information indicating a category of the broadcast service and bootstrapping information to obtain a service signaling information for the broadcast service, the service signaling information is transmitted via either the broadcast network or a broadband network that is different from the broadcast network; time de-interleaving the signal frame; parsing the signaling table to acquire the service signaling information, the service signaling information is acquired via: the broadband network based on a bootstrapping information that includes URL (Uniform Resource Locator) information of the service signaling information, or the broadcast network based on a bootstrapping information that includes an IP (Internet Protocol) address of an IP packet carrying the service signaling information; and parsing the service signaling information including transport session information for one or more transport packets carrying one or more SGDDs (Service Guide Delivery Descriptors).

Systems and methods for replacing a portion of a broadcast content with a customized, live-streaming alternate media stream are provided. Usable by applications developed for the Web, mobile devices, laptop or desktop computers, or broadcast television, the system includes a broadcast server to prepare customized media streams for a particular broadcast in communication with a client receiver capable of receiving a customized media stream and synching the stream with the particular broadcast of interest. Thus, the user may view the original broadcast with the alternative audio or video stream, in some cases in near real-time, and enjoy the alternative media stream seamlessly with the original broadcast. In order to provide the capabilities disclosed herein, a fingerprinting method is used to analyze the original broadcast and synchronize timing, without modifying the original broadcast data.

Systems and methods for replacing a portion of a broadcast content with a customized, live-streaming alternate media stream are provided. Usable by applications developed for the Web, mobile devices, laptop or desktop computers, or broadcast television, the system includes a broadcast server to prepare customized media streams for a particular broadcast in communication with a client receiver capable of receiving a customized media stream and synching the stream with the particular broadcast of interest. Thus, the user may view the original broadcast with the alternative audio or video stream, in some cases in near real-time, and enjoy the alternative media stream seamlessly with the original broadcast. In order to provide the capabilities disclosed herein, a fingerprinting method is used to analyze the original broadcast and synchronize timing, without modifying the original broadcast data.

A method and system for transmitting and receiving an audio signal over a video signal in a single cable. The method and system including receiving an analog video signal, the analog video signal comprising one or more rows of video data, an audio header, and one or more quantized audio data. The method includes detecting, the audio header in a blank interval of the analog video and determining a reference level of the audio header. The method and system include extracting, in response to detecting the audio header, the one or more quantized audio data and converting the one or more quantized audio data to an original value of audio data based on the reference level of the audio header. The method and system are configured for storing the one or more quantized audio data in the original value in a First-in-First-Out (FIFO) buffer, and reconstructing, utilizing the FIFO buffer, a continuous audio signal from the one or more quantized audio data in the original value.

A broadcast reception method includes: receiving a broadcast signal including service data and signaling information for a service, wherein the signaling information includes first signaling information for acquisition of the service, wherein the signaling information includes second signaling information including bootstrap information for the service; acquiring the service data on the basis of the signaling information; and decoding the service data, wherein the signaling information includes electronic service guide (ESG) bootstrap information for ESG data.