Abstract: A method and apparatus for applying tonal correction to images to obtain a more pleasing photographic image by redistributing low-key, mid-tone and high-key tones. Luminance is calculated by using formulas appropriate for the color space or directly inputted. Two color-difference components are computed for the original image. Luminance is subjected to a tonal correction function to obtain a tonal corrected luminance. Luminance gain is calculated and applied to the color-difference components to obtain two tonal corrected color-difference components. The tonal corrected luminance and two tonal corrected color-difference components can be directly output or used to calculate three color component signals for the desired color space.

Abstract: A programmable gain amplifier (PGA) includes a sample-and-hold (S&H) stage which provides an input capacitance value for storing a charge. The PGA also includes an amplifying stage, which has a gain dependent on the input capacitance value. The amplifying stage is configured to provide a variable gain, while the S&H stage is configured to provide a substantially constant input capacitance value, regardless of the gain.

Abstract: Automatic gain control is provided for a confocal imaging system to improve the quality of images produced by the system. The confocal imaging system utilizes an illumination source, such as a laser, to produce illumination which enables imaging of an object. The automatic gain control is provided by an automatic gain controller which operates in accordance with the counted number of pixels which are too bright, the counted number of pixels which are too dim, and the counted total number of pixels, or in accordance with the average value of pixels, of each two-dimensional frame of the images from the confocal imaging system to control the intensity of the illumination source. The automatic gain controller may be operative over either the entire frame, or a region thereof.

Abstract: An intended-usage judger judges an intended usage of an inputted digital imaging signal. A selector selects one or a plurality of signals to be inspected from a group of signals constituting the digital imaging signal based on a result of the judgment by the intended-usage judger. A phase adjuster adjusts a phase of a pulse used when the digital imaging signal is picked up based on an output state of the signal to be inspected.

Abstract: A visual processing section 120 is provided which performs visual processing on a pixel-by-pixel basis according to a predetermined function defining a relation between a pixel value of a target pixel which is a pixel under visual processing and a pixel value of the target pixel after subjected to the visual processing. An input signal processing section 150 is further provided which performs, on a pixel-by-pixel basis, at least one of signal processing to restore resolution of an image data input to the visual processing section 120 and signal processing to correct signal deterioration due to the visual processing. In the input signal processing section 150, the at least one signal processing is performed according to a gain determined by using the function.

Abstract: An object of the present invention is to provide an image processing apparatus that obtains a high-quality image signal by determining an amount of noise in an optimum fashion and reducing the amount of noise. The image processing apparatus reduces a noise component contained in the image signal picked up by an image pickup element and digitized. The image processing apparatus includes a determining unit which determines whether or not a target pixel in the image signal is within a predetermined noise range for each pixel, and a noise reducing unit which reduces the noise of the target pixel based on the determination result.

Abstract: An apparatus comprising a first circuit and a second circuit. The first circuit may be configured to determine frequency of occurrence information for a range of gray levels from luminance data of an input signal. The second circuit may be configured to selectively adjust enhancement for at least one portion of the range of grey levels based upon the frequency of occurrence information.

Abstract: The invention achieves a visual processing device that can execute precise contrast adjustment on image signals that have been input and that does not cause discrepancies in the output timing of the image signals that are output. The visual processing device is provided with a gain-type visual processing portion that outputs a first gain signal having predetermined gain characteristics with respect to the input image signal, and a correction portion that corrects the input image signal based on the first gain signal.

Abstract: The invention achieves a visual processing device that can execute precise contrast adjustment on image signals that have been input and that does not cause discrepancies in the output timing of the image signals that are output. The visual processing device is provided with a gain-type visual processing portion that outputs a first gain signal having predetermined gain characteristics with respect to the input image signal, and a correction portion that corrects the input image signal based on the first gain signal.

Abstract: A video signal processing circuit converting a color image represented using a plurality of primary color signals into a monocolor image is provided. The video signal processing circuit includes: a chroma adjustment unit adjusting the chroma of the plurality of input primary color signals; a gain correction unit provided for each of the primary color signals, correcting gain on the primary color signals whose chroma is adjusted in the chroma adjustment unit; and a control unit instructing the chroma adjustment unit to adjust the chroma and instructing each of the gain correction units to correct the gain.

Abstract: An imaging apparatus for capturing an image using a solid-state imaging device includes the following elements. One or more signal correction units correct an image signal obtained by capturing the image on a color component basis. A luminance detection unit detects luminance information from image signals obtained at locations prior to and subsequent to at least one of the signal correction units. An exposure control unit controls an exposure adjustment mechanism on the basis of the luminance information detected by the luminance detection unit.

Abstract: An analog signal chain for a CMOS active pixel sensor imaging system utilizes, for each amplification stage, a plurality of fixed gain amplifiers instead of a single multi-gain amplifier. The fixed gain amplifier corresponding to the desired gain level is selected and powered on and coupled to the input/output signal paths, while the non-selected fixed gain amplifier(s) are powered off and isolated from the input/output signal paths. Each fixed gain amplifier is operated at a gain bandwidth corresponding to the timing requirements of the imaging system and the gain of the amplifier. Thus, each fixed gain amplifier (other than the one corresponding to the maximum gain of a comparable multi-gain amplifier) operates at a lower level of power consumption than the comparable multi-gain amplifier.

Abstract: This invention provides an image processing device and a printing apparatus that obviate the need for manual processing on the part of the user or operator and which can automatically perform an optimum image correction without using added information such as photographing information. For this purpose, this invention including: a highly chromatic color area detection unit to detect highly chromatic color area in an original image according to the input color image data; a concentration calculation unit to calculate a concentration level of the highly chromatic color area; and a print data generation unit to generate output color image data according to the concentration level of the highly chromatic color area.

Abstract: An imaging processing device and method where, when areas having a luminance difference set by a user, for example, 45 dB or more, are preset in an image captured by a camera, an area, the luminance level of which exceeds a predetermined threshold level, may be displayed as a gray level or a black level, with the luminance thereof decreased by a certain luminance level, or may be displayed while a mask, having a gray or black level, and the area, the luminance level of which exceeds the predetermined threshold level, overlap each other. Therefore, glare caused by a high luminance subject can be decreased, or other subjects present in a backlit image can be easily recognized.

Abstract: An image-data processing apparatus includes an operation unit; a correcting unit multiplying image data generated by an image pickup device by a correction gain; a totalizing unit sequentially calculating a total pixel level for every frame from the image data; a history holding unit holding the total pixel levels of a certain number; an in-phase averaging unit detecting the total pixel levels in phase with a flicker phase corresponding to the image data that is being supplied to the correcting unit from the held total pixel levels to calculate a first average of the detected total pixel levels; an average calculating unit calculating a second average of the held total pixel levels; and a correction gain calculating unit calculating the correction gain by dividing the first average by the second average to set the correction gain in the correcting unit.

Abstract: A method, apparatus, and system that use a white balance operation. A selecting process is applied to each pixel selected and considered for automatic white balance statistics to determine the distance from the selected pixel to a white curve defined in a white area corresponding to an image sensor.

Abstract: An image pickup apparatus is disclosed which can remove noise with certainty from an image pickup signal while a high resolution of the image pickup signal is assured regardless of a reading out method of the image pickup signal and achieve reduction of the cost. A light receiving face of a solid-state image pickup device has an image pickup region from which a detection signal corresponding to an image of an image pickup subject formed from light incoming to the light receiving face is outputted as an image pickup signal and a light amount detection region from which a detection signal corresponding to the amount of the light incoming to the light receiving face is outputted as a light amount detection signal. A signal processing circuit of a signal processing section processes the image pickup signal to produce a video signal. A detection circuit detects cyclic variation of the luminosity of a light source from the light amount detection signal.

Abstract: An image processing method comprising a step of performing a color interpolation process on image data output from a single-chip color image capturing sensor to calculate color data for each pixel and a step of converting the color data using a predetermined transformation formula and of filtering the converted data, and the transformation formula is replaced based on the magnitude of a color value of the color data. When a color value of a specific color is large, the transformation formula can be appropriately changed. Therefore, it is possible to prevent the lowering of the overall resolution without being affected by the resolution of the color. Further, it is possible to reliably reproduce a smooth and natural edge of an image without adding other processes to the color interpolation process.

Abstract: A method of automatically adjusting parameters of a display device is provided. The method includes: measuring a current distance between a user and the display device; determining a particular distance range which the current distance falls in; determining corresponding parameter values of the particular distance range according to a parameter management table which lists a series of distance ranges and corresponding parameter values of the display device; transmitting the parameter values to the display device; adjusting parameters of the display device according to the parameter values.

Abstract: According to one embodiment, in the case where a non-linear correction processing is performed in a direction in which an amplitude level of a luminance signal is heightened, an amplitude level correction processing is performed to a color signal on the basis of a first coefficient read from a first table prepared in advance in correspondence to the case. In the case where a non-linear correction processing is performed in a direction in which the amplitude level of the luminance signal is lowered, an amplitude level correction processing is performed to the color signal on the basis of a second coefficient read from a second table prepared in advance in correspondence to the case.

Abstract: The anti-blooming structure of an image sensor is supplied with varying voltages during different integration periods such that charges generated in response to low level light are fully captured, whereas charges generated in response to a bright light spill over in a controlled manner. Accordingly, sensor's response may be generated to result in higher gains at low light levels and progressively lower gains at the higher light levels.

Abstract: An image-pickup apparatus includes an image-pickup element including first pixels photoelectrically converting an object image formed by a light flux from an image-pickup optical system and second pixels including plural focus detection pixels photoelectrically converting a light flux divided from the light flux from the image-pickup optical system, a focus detector detecting a focus state of the image-pickup optical system based on outputs from the second pixels, a frequency component detector detecting a spatial frequency component of the object image formed on the first pixels, an image generator generating, based on outputs from the first pixels, a partial image corresponding to the second pixels of an image obtained by an output from the image-pickup element. The apparatus includes a controller switching whether or not to cause the image generator to generate the partial image according to the spatial frequency component detected by the frequency component detector.

Abstract: Systems and techniques for processing sequences of video images involve receiving, on a computer, data corresponding to a sequence of video images detected by an image sensor. The received data is processed using a graphics processor to adjust one or more visual characteristics of the video images corresponding to the received data. The received data can include video data defining pixel values and ancillary data relating to settings on the image sensor. The video data can be processed in accordance with ancillary data to adjust the visual characteristics, which can include filtering the images, blending images, and/or other processing operations.

Abstract: A high dynamic range sensitive sensor element or array is provided which uses phase domain integration techniques to accurately capture high and low intensity images. The sensor element of the present invention is not limited by dynamic range characteristics exhibited by prior art solid-state pixel structures and is thus capable of capturing a full range of electromagnetic radiation to provide a high quality output image.

Abstract: An image sensing apparatus executes a plurality of tone corrections respectively suited to different luminance distributions of images. The image sensing apparatus analyzes a luminance distribution of sensed image data, selects, based on an analysis result, at least one of a first tone correction which suppresses luminance saturation of image data, a second tone correction which converts luminance values of all luminance regions so that a maximum luminance value of sensed image data becomes a largest possible luminance value of the image data, and a third tone correction which multiplies a luminance value of a low-luminance region, which is set in advance, of sensed image data by a gain larger than gains of other luminance regions, as a tone correction to be implemented for sensed image data, and limits, when a correction based on the second tone correction is selected, implementation of a correction based on the third tone correction.

Abstract: A receiving apparatus includes: a signal-level detecting unit detecting a signal level of an input signal; a first signal-level converting unit including amplifiers, capturing the input signal and converting a signal level of the input signal; a switching unit switching an output of a signal whose level is converted by the amplifiers; a switching control unit selecting a specific amplifier out of the amplifiers and controlling the switching unit to select an output signal from the selected amplifier; a band-pass filter allowing only a predetermined frequency band in the signal, the output of which is switched by the switching unit, to pass; a second signal-level converting unit converting a signal level of an output signal from the amplifier into a predetermined signal level; a mixer mixing the signal passed through the band-pass filter, the signal level of which is converted by the second signal-level converting unit, and an oscillation signal to generate an intermediate frequency signal; and a demodulating

Abstract: The disclosed is to provide an image signal processor and its method in which the enhancement of resolution and the effective reduction of noise are compatible. The image signal processor is provided with an edge character detector that detects a character of an edge of an object, an image signal frequency zone limiter that executes a noise removing process, an image signal frequency zone enhancer that executes a resolution enhancing process and a gain controller that changes each intensity of the image signal frequency zone limiter and the image signal frequency zone enhancer according to an output result of the edge character detector.

Abstract: The invention achieves a visual processing device that can execute precise contrast adjustment on image signals that have been input and that does not cause discrepancies in the output timing of the image signals that are output. The visual processing device is provided with a gain-type visual processing portion that outputs a first gain signal having predetermined gain characteristics with respect to the input image signal, and a correction portion that corrects the input image signal based on the first gain signal.

Abstract: A variable-gain amplifier circuit and a method of changing gain amplifier paths are provided for receiving and amplifying an image sensing signal. The variable-gain amplifier circuit includes variable path and gain amplifier circuits. According to the amplification factor for the image sensing signal, the gain amplifier paths in the variable path and gain amplifier circuits are changed based on a control signal, so as to achieve the appropriate construction of the variable-gain amplifier circuit. The image sensing signal generates the required image result through appropriate numbers of variable gain amplifiers, thereby decreasing the power consumption of the circuit and reducing the design requirement of the circuit.

Abstract: Automatic white balance of captured images can be performed based on a gray world assumption. Initially, a flat field gray image is captured for one or more reference illuminations. The statistics of the captured gray image are determined and stored for each reference illumination during a calibration process. For each subsequent captured image, the image is filtered to determine a subset of gray pixels. The gray pixels are further divided into a one or more gray clusters. The average weight of the one or more gray clusters is determined and a distance from the average weights to the reference illuminants is determined. An estimate of the illuminant is determined depending on the distances. White balance gains are applied to the image based on the estimated illuminant.

Abstract: A method of generating a gain of an image frame according to a look up table of gain which is set up based on luminance sensitivity of human eyes is proposed. The method includes setting a gain of an image frame to 1, scanning images of a plurality of front rows of the image frame, averaging the images of the plurality of the front rows of the image frame to generate an average value of the images of the plurality of the front rows of the image frame, finding a gain from the look up table of gain according to the average value of the images of the plurality of the front rows of the image frame, and adjusting remaining rows of the image frame according to the gain to generate images of the remaining rows of the image frame.

Abstract: An imaging apparatus of the present invention includes an optical lens unit of a photographic optical system; an imaging device for converting light received through the optical lens to electrical signals; a zooming device for changing a focal length of the photographic optical system; a zooming position detector for detecting a current zooming position; an A/D converter for converting analog image signals outputted from the imaging device to digital image signals; and a gradation sequence converter which converts a gradation sequence characteristic of the digital image signals by referring to a gradation sequence conversion table for converting the gradation sequence characteristic, wherein converting amounts of the gradation sequence conversion table are changed based on a current zooming position detected by the zooming position detector.

Abstract: To reliably obtain a captured image expected by a user, such as an image precisely showing the shades of a blue sky or a flower, or an image captured under flat illumination and having high contrast, an apparatus comprises an aperture, shutter, CCD, and an AGC, and applies gamma correction to an image signal using gamma correction values. Maximum reflectance, being an index of the amount of incident light according to the maximum output from the CCD, is increased or decreased in multiple levels depending on the subject being photographed, and the exposure amount is accordingly adjusted, thereby changing a dynamic range. A microcomputer revises the gamma correction values in response to changes in maximum reflectance so as to substantially maintain a relationship between an incident light reference amount being a reference for appropriate exposure and the corresponding gamma corrected output value.

Abstract: A dc level control method for holding a dc level of a clamp portion in an electric signal to be a prescribed value is disclosed, wherein the method comprises the steps of: comparing a dc level of a sampling interval in said electric signal with a predetermined reference value to obtain a difference between said dc level and said reference value using an A/D converting section for dc level comparison which has a lower bit resolution than an A/D converting section for digital signal processing of said electric signal; and feeding back a clamp signal to said electric signal so that said obtained difference between said dc level and said reference value substantially becomes zero. This method is suitable for applying to a signal processing system for a solid state imaging apparatus.

Abstract: An A/D converter 11 performs multiple-times sampling on a first signal S1 in a first period T1 while performing multiple-times sampling on a second signal S2 in a second period T2. An A/D converter circuit 17 provides a digital signal in response to a signal from an output 15b of a gain stage 15 in the second period T2. The digital signal may have a value “1” or a value “0”. The A/D converter circuit 17 includes a circuit 18 providing a signal SA/DM corresponding to the number of times the value “1” appears. A switch 24 operates in response to a clock signal ?s and is used to sample a signal from a pixel 2a. In a first capacitor circuit 27, a switch 29 and a capacitor 31 are connected to an inverting input 23a and a non-inverting output 23b, respectively. The switch 29 operates in response to a clock signal ?3 and is used for integration in the capacitor 31.

Abstract: The digital camera comprises: an image-taking device for converting light from a subject to a video signal and outputting the video signal; an image processor which has a gain adjuster for performing gain adjustment individually for respective color information of R, G, B of the video signal outputted from the image-taking device, and an image data converter for converting the adjusted video signal outputted from the gain adjuster into image data; a displaying device for displaying the image data; a setting device; and a controller for controlling the gain adjuster to perform RGB color discrimination of the video signal and gain adjustment individually on the respective color information by a command from the setting device.

Abstract: A gain control circuit includes a light detector for generating an amount of current based on received light and a first switch for controlling the amount of current from the light detector delivered to a node. The gain control circuit also includes a charge storage element for providing an amount of capacitance to the node and a second switch for controlling the amount of capacitance provided to the node. The gain control circuit further includes an output interface for delivering an output signal based on the amount of current and the amount of capacitance at the node. The light detector may include multiple photodiodes, and the first switch may include a pair of NMOS switching transistors coupled to at least one photodiode. Also, the charge storage element may include multiple capacitors, and the second switch may include a PMOS transistor and an NMOS transistor coupled to each capacitor.

Abstract: An inspection tool includes a camera having a gain value and an offset value set to provide a first camera output indicating a first desired average gray value when the camera is illuminated with a precision light source set at a first light level. The inspection tool includes an inspection light source configured to be set at a second light level such that when the inspection light source illuminates a known target, the camera provides a second output indicating a second desired average gray value.

Abstract: It is an object of the present invention to provide a video processing apparatus which can perform separately two shading corrections including a dark shading correction of an image and a peripheral shading correction for light falloff at edges of the image, and can calculate, with accuracy, correction gains corresponding to respective pixels from the correction values of blocks.

Abstract: An image sensor and digital gain compensation method thereof. The image sensor comprises a variable amplification device for amplifying an inputted analog image signal as a variable first gain value, an analog-to-digital conversion unit for converting the amplified analog image signal into a digital image signal, and a digital gain compensation device for comparing the first gain value with a reference gain value and compensating the digital image signal as a digital second gain value when the first gain value is less than the reference gain value.

Abstract: A digital camera (10) includes a CCD imager (16). A long-time exposure image signal obtained by a long-time exposure of the CCD imager (16) is applied to a terminal (S1) of a switch (SW1), and a short-time exposure image signal obtained by a short-time exposure of the CCD imager (16) and a gain adjustment is applied to a terminal (S2) of a switch (SW2). A CPU (44) controls the switch (SW1) by comparing a Y level of the long-time exposure image signal with a reference value Ys so as to generate a combined image signal. More specifically, the CPU (44) connects the switch (SW1) with the terminal (S1) when a condition of Y level?Ys is satisfied, and connects the switch (SW1) with the terminal (S2) when a condition of Y level>Ys is satisfied. The CPU (44) detects a color deviation degree of an object prior to generation of the combined image signal and reduces the reference value Ys on the basis of a detection result.

Abstract: An image combined high sensitivity image and low sensitivity image is provided with well-adjusted white balance and broad dynamic range. The image is obtained by multiplying the combined data by total gain that depends on scene. A white balance is adjusted with gain value calculated from of high output image data. Lv value representing luminance is calculated and compared with a threshold to decide whether or not the high sensitivity image and the low sensitivity image should be combined. First gamma correction unit performs gamma-correction for the image signal derived from the high sensitivity signal with first gamma character, second gamma correction unit performs gamma-correction for the image signal derived from the low sensitivity signal with second gamma character that is different from the first gamma character, and addition unit combines the image signal from the first gamma correction unit and the image signal from the second gamma correction unit.

Abstract: An imaging apparatus includes a first output unit configured to perform first gain processing on an analog signal corresponding to an electric charge stored in a photoelectric conversion element in a first region and output the processed signal, a second output unit configured to perform second gain processing on an analog signal corresponding to an electric charge stored in a photoelectric conversion element in a second region and output the processed signal, an instruction unit configured to instruct a gain of each gain processing in the first and second output units, a first control unit configured to control a display of an image based on an output signal from the first output unit, and a second control unit configured to control an imaging condition based on an output signal from the second output unit. The second gain processing is different from the first gain processing.

Abstract: A programmable gain amplifier (PGA) includes a sample-and-hold (S&H) stage which provides an input capacitance value for storing a charge. The PGA also includes an amplifying stage, which has a gain dependent on the input capacitance value. The amplifying stage is configured to provide a variable gain, while the S&H stage is configured to provide a substantially constant input capacitance value, regardless of the gain.

Abstract: In a color-noise reduction circuit in which a color-difference signal of a target pixel is substituted in a random substitution circuit 104 by a color-difference signal of another pixel within an area including the target pixel, a pixel-substitution color-difference signal that is the substituted signal whose high-frequency components are removed in an LPF 106 and the color-difference signal of the target pixel are added together in a summation circuit 108 at a predetermined ratio obtained by a pixel-substitution utilization rate calculation circuit 107, and is outputted as a noise-reduced color-difference signal of the target pixel. Therefore, efficient color-noise reduction and suppression of occurrence of color jitters can be realized.

Abstract: An intended-usage judger judges an intended usage of an inputted digital imaging signal. A selector selects one or a plurality of signals to be inspected from a group of signals constituting the digital imaging signal based on a result of the judgment by the intended-usage judger. A phase adjuster adjusts a phase of a pulse used when the digital imaging signal is picked up based on an output state of the signal to be inspected.

Abstract: In an analog front end (FE) IC chip having a CDS (Correlated Double Sampling) function and an AGC (Automatic Gain Control) function, a clamp circuit for clamping an output signal during a black reference signal period is equipped with a mechanism for suppressing the effect of noises contaminated from a power source, external circuits, etc.

Abstract: A video decoder (10) for receiving an input video signal and producing output signals for a digital display (12), and involving automatic gain control (AGC) functions (20, 28), is disclosed. For each of the front-end and back-end AGC functions (20, 28), the AGC gain value applied is modified according to measurements of several attributes of the video signal, such as sync height, color burst amplitude, composite signal peak amplitude, and luma signal peak amplitude. The measurements are made, and the AGC gains are modified, on a frame-by-frame basis. Preferably, the AGC is modified using the one of the signal attributes that indicates the lowest gain. The back-end AGC function (28) modifies its gain to unity if the front-end AGC function (20) selected the luma signal peak amplitude for modifying its gain. A method for adjusting the rate of change of the AGC gain is also disclosed, in which gain increases are delayed and slowed following an AGC gain decrease because of an image-dependent signal attribute.

Abstract: A system for generating a digital output signal representing a captured image includes a sensor for capturing the image and generating a sensor output signal. A gain control amplifier is coupled to the sensor and receives the sensor output signal. The gain control amplifier has controls for applying various levels of gain to the sensor output signal. An analog-to-digital converter is coupled to the gain control amplifier and generates the digital output signal representing the captured image. A processor is coupled to the analog-to-digital converter and the gate control amplifier. The processor provides a control signal to the gain control amplifier for adjusting the level of gain applied by the amplifier.

Abstract: A system for generating a digital output signal representing a captured image includes a sensor for capturing the image and generating a sensor output signal. A gain control amplifier is coupled to the sensor and receives the sensor output signal. The gain control amplifier has controls for applying various levels of gain to the sensor output signal. An analog-to-digital converter is coupled to the gain control amplifier and generates the digital output signal representing the captured image. A processor is coupled to the analog-to-digital converter and the gain control amplifier. The processor provides a control signal to the gain control amplifier for adjusting the level of gain applied by the amplifier.