TH32558B - Method of reducing the interference elements in a correlated digital signal. - Google Patents

Abstract

DC60 (31/07/41) The noise element is extracted from the correlated digital input signal, such as the digital image signal, in which the image information is the same. critically from one frame to the next. The noise that has been extracted is obtained. Multiplying by a feedback coefficient that varies nonlinearly with respect to the noise value. extracted Such feedback coefficients are switched on a random basis or pseudorandom. The noise component is extracted from the correlated digital input signal, such as the digital video signal in which The image information is the same. critically from one frame to the next. The noise that has been extracted is obtained. Multiplying by a feedback coefficient that varies nonlinearly with respect to the noise value. The extraction of such feedback coefficients is switched on either a random basis or pseudorandom.

Claims (2)

1. A method of reducing the noise component in a correlated digital signal in which It consists of the steps of: Recognizing the uncorrelated elements in such digital signals to produce the displayed magnitude. instead of this element; Such correction of the perceived element gain is achieved by a non-linear coefficient K, where K represents the value of <=1 and that value of K is a function of the element size value. Assemblies that have been recognized as such; Switching between tables of K where different data is stored, in which the value of K in one of the tables of that repository is different from the value of K in another of such repository tables; By generating a multi-bit signal M series, generating a multi-twist control signal of a user-selected value, combining such an M-serial signal with that control signal and selecting a stored table of K as a function of the signal. included therein ; and removal of the detected and gain-adjusted elements from the signal. such digital to produce a digital signal that has undergone noise reduction. 2. Method of claim 1, in which the digital signal with such correlation is digital photo 3. Method of claim 2, such digital video signal includes luminance (monochrome signal) and chrominance (color signal) components and such uncorrelated elements. Only the luminance component is examined. 4. Method of claim 2, which digital video signal includes luminance and chrominance components. Such non-unioned elements will be recognized as elements. uncorrelated luminance and uncorrelated chrominance elements, luminance elements and uncorrelated chrominance The gain-adjusted luminance and non-correlation chrominance elements, which are gain-adjusted, are removed. from the luminance and chrominance components of the digital image signal, respectively. It consists of the process of collecting pre-defined intervals of the video signal. such digital and erasing digital video signals that have been stored away from the range 6. Method of Claim Article 5 in which such pre-defined interval is one frame 7. Method of Claim Article 5 in which the signal The digital image in which the data is stored will be Digital video signal that has undergone noise reduction. 8. Method of claim 7, which is further supplemented. Stage of signal decimate digitally before the aforementioned non-correlated elements. A gain-modified element is detected and removed from the decimate digital video signal to produce a decimate digital signal. which has passed the noise reduction in such a way that A decimate digital video signal that has undergone noise reduction is stored. K's aforementioned stored data is processed in a random 1 0.1 method of claim 1, in which the procedure of such switching between the stored tables. The aforementioned information of K is performed in a pseudorandom manner 1. 1. Method of claim 1 in which each signal of such M-serial signal and the Such a control is an n-bit signal in which the summated signal consists of n+1 bit signals and the stored table of K is chosen as a function of the most significant bit of the n-bit signal. n+1 such bits 1 2. A successful machine for reducing the noise component in a correlated digital signal, which consists of A detection method for detecting the uncorrelated elements in such digital signals. to produce a magnitude value that replaces this element. Non-linear path for modulating the size ratio of the detected elements. Such is the nonlinear coefficient K, where K represents a value at O<=K<=1 and such value of K is a function of the magnitude value of the element to be detected , the way that not as linear In other words, it includes a number of K's repository tables where the value of K in the first table of the repository table. The data differs from the value of K in the other table of the table where the data is stored. The method for switching between different tables of K's aforementioned repository tables to select tables for which said coefficient K is selected from that table. Combined method for creating multi-bit serial signal M, a path for generating a multi-bit control signal of a user-selected value. A pathway for summing such M-series signal to that control signal, and a path for selecting the first K repository table as a function of the aggregated signal, and a negative pathway for subtracting the passive element. Adjust the gain and exit the signal. such digital To produce a digital signal that has passed the noise reduction. Digital Imaging 1 4. The finished device of Claim 12, which includes digital video signals. with luminance and chrominance elements and such sensing methods will detect the elements that There is no correlation only in the aluminium components only. with luminance and chrominance elements and such sensing methods will detect the elements that no correlation as It is the uncorrelated luminance component and the non-correlated chrominance component. Such nonlinear path will adjust the gain of the luminance element and Such perceived uncorrelated chrominance and such negative pathways are composed. Luminance and uncorrelated chrominance which has been adjusted for gain and then leaves the element Luminance and chrominance of such digital video signal respectively 1. for the pre-defined interval of the digital video signal and the path for deleting the stored digital video signal. Leaving the interval that follows the next phase Displacement of such digital video signal 1 7. The completion of Claim 16, where the pre-defined interval will be one frame 1 which has been stored It will be a digital video signal that has undergone noise reduction. Decimate the digital image signal before the aforementioned uncorrelated component. will be examined and a method for removing gain-optimized elements from a linear video signal. Decimate digital to produce digital image signals that have been decimate through which the reduction already scrambled in such a way that Decimate digital video signal that has been reduced The interference is then stored. 2 0. The machine succeeds of Clause 12, which means for such a switch. between the tables Such stored data of K will be executed in random manner 2. 1. A successful device of Clause 12, which means for such a switch between the tables Such stored data of K will be executed in an pseudorandom random manner 2. 2. An instrument of claim 12, where each signal of such M-serial signal and such control signal is an n-bit signal, the combined signal consists of n+1 bits and such paths. For the selection of K's stored tables, it can be performed to select one of them as a function of the most significant bits of the signal and n+1 bits.