KR20000018762A - Digital correcting apparatus of a infrared ray detector and method thereof - Google Patents

Abstract

PURPOSE: A digital correcting apparatus is provided to correct a gain and an offset with a frame rate of a predetermined frequency by controlling a reference temperature source using a histogram of an input image. CONSTITUTION: The digital correcting apparatus comprises: an infrared ray detector(1) for detecting an infrared ray image signal(IR_V) and reference temperatures(T1, T2), from a reference temperature source(10), to convert the detected signals into an electric signal, respectively; an A/D converter(2) for converting the electric signal of the analog into a digital signal; a first memory(3) for storing a digital reference temperature signal from the converter(2); a second memory(4) for storing an image signal; a processor(5) for calculating an ununiform correcting value and a reference temperature value on the basis of an output signal of each memory(3, 4); a third memory(6) for storing a gain correcting value calculated by the processor; a fourth memory(7) for storing an offset correcting value; a digital operator(8) for operating output values from the second to fourth memories with a frequency field rate to generate an image output signal(S) free of an ununiformity; and a reference temperature controller(9) for finely controlling the a lower reference temperature(T1) and a higher reference temperature(T2).

Description

Digital Correction Device and Method of Infrared Detector

The present invention relates to a digital correction technique for correcting an output signal unevenness of a focal plane array infrared detector in real time. Particularly, a spatial noise (fixed pattern noise) can be precisely corrected by precisely compensating a difference in output voltage between detection elements to a thermal noise level of a detector. The present invention relates to a digital correction apparatus and method for an infrared detector that is suitable for removal.

Focal plane array infrared detectors, commonly referred to as second-generation image detectors, are very sensitive, ranging from thousands to tens of thousands of detection elements, and with an equal noise temperature difference of 5 to 30 mK, resulting in excellent image resolution and high signal-to-noise ratio. The noise caused fixed pattern noise in the reproduced image, which caused not only the image quality but also the worsening of the minimum resolution temperature difference, which is the performance index of the thermal imaging equipment. Therefore, thermal imaging equipment using a focal plane array infrared detector requires a correction circuit for uniformizing the output signal.

The output signal non-uniformity of the infrared detector is due to the difference between the signal gain and the DC offset of the detection element for the infrared input energy, that is, the input temperature signal. This characteristic is summarized by the following equation (1).

Where V _i is the output voltage of the i th detection element, T is the input temperature signal, the first term is the signal gain of each detection element, and the second term is the DC offset component due to the dark current. As a result, non-uniformity correction of the focal plane array infrared detector means matching the gain and offset difference between detection elements with the same magnitude for the same input temperature signal.

Since the first generation of thermal imaging equipment has only a few dozen detection elements, a method of correcting gain and offset using an analog amplifier is used. However, since the second generation thermal imaging equipment has tens of thousands of detection elements, it is practically impossible to implement an analog correction circuit.

Therefore, most second-generation thermal imaging equipment uses a digital method of measuring the output of a focal plane array infrared detector in advance to obtain a gain and offset, and storing the value in a ROM to correct it.

As described above, the second generation thermal imaging apparatus uses a digital method of measuring the output of the focal plane array infrared detector in advance to obtain a gain and offset, and storing the value in a ROM to compensate for it. When the value is applied to an input image with a different temperature, there is a defect that causes residual noise due to a complete correction.

Therefore, the technical problem to be achieved by the present invention is to control the reference temperature source by using the histogram of the input image, to adaptively correct the gain and offset at a frame rate of a predetermined frequency (for example, 30 Hz), and to correct the correction process in real time. It is to provide a digital correction apparatus and method for performing.

1 is a digital correction block diagram of an infrared detector according to the present invention.

Figure 2 is a histogram / cumulative distribution graph showing the reference temperature control principle according to the present invention.

Figure 3 is a signal flow diagram of the digital correction method of the infrared detector according to the present invention.

* Description of the symbols for the main parts of the drawings *

1: Focal plane array infrared detector 2: A / D converter

3: first memory 4: second memory

5 processor 6 third memory

7: 4th memory 8: Digital calculator

8A: Multiplier 8B: Adder

9: reference temperature controller 10: reference temperature source

1 is an exemplary block diagram of a digital correction apparatus for an infrared detector for achieving the object of the present invention, as shown in the figure, by detecting the infrared image signal (IR_V) and the reference temperature (T1), (T2), respectively A focal plane array infrared detector (1) for converting the signal into an electrical signal; An analog (A) / digital (D) converter (2) for video signal processing for converting an analog signal output from the focal plane array infrared detector (1) into a digital signal of a predetermined bit; A memory for storing a digital reference temperature signal output from the A / D converter (2), the first memory (3) for updating an output signal of each detection element at a predetermined frequency field rate; A video memory for storing the digital video signal output from the A / D converter (2), the second memory (4) for updating the video signal at a predetermined frequency field rate; A processor (5) for calculating a non-uniformity correction value and a reference temperature (T1), (T2) value based on the output signals of each of said memories (3) and (4); A third memory (6) for storing a gain correction value calculated by the processor (5) for updating at a predetermined frequency field rate; A fourth memory (7) for storing the offset correction value calculated by the processor (5) for updating at a predetermined frequency field rate; A real-time digital calculator consisting of a multiplier 8A and an adder 8B, which calculates a non-uniformity of a predetermined bit based on an output value of each of the memories 4, 6, and 7 and corrects unevenness. A digital calculator 8 for generating a signal S; A reference temperature controller 9 for precisely controlling the low reference temperature T1 and the high reference temperature T2 of the reference temperature source 10 by receiving values of the reference temperatures T1 and T2 from the processor 5; ; The reference temperature source (10) provides a reference temperature (T1), (T2) for the non-uniformity correction of the focal plane array infrared detector (1) using an internal thermoelectric cooling element, the configuration of the present invention Referring to Figures 2 and 3 attached to the operation in detail as follows.

The focal plane array infrared detector 1 detects the infrared image signal IR_V and the reference temperatures T1 and T2 and converts them into electrical signals, and the A / D converter 2 outputs the focal plane array infrared rays. The analog video signal and the reference temperature signal output from the detector 1 are converted into digital signals of predetermined bits (eg, 12 bits) and output.

The digital reference temperature signal output from the A / D converter 2 is stored in the first memory 3, and the digital image signal is stored in the second memory 4. The output signal of each of the detection elements stored in the first memory 3 and the digital image signal stored in the second memory 4 are respectively updated at a predetermined frequency (eg, 60 Hz) field rate.

On the other hand, the processor 5 calculates the non-uniformity correction value and the reference temperature (T1), (T2) value based on the output signals of the respective memory (3), (4), and detects here as a processor for controlling the digital compensator. The nonuniformity correction coefficient of each element is calculated by the following equation (2).

In Equation 2, g _i is a gain correction coefficient, o _i is an offset adjustment coefficient, and R (T1) and R (T2) are reference values for non-uniform matching at the reference temperatures (T1) and (T2). In the present invention, the output voltages of the detection elements stored in the first memory 3 are averaged and used as reference values.

In addition, the reference temperature (T1), (T2) is calculated by using the histogram of the image signal stored in the second memory (4), for this purpose to obtain a cumulative distribution function from the histogram of the image, as shown in FIG. The low reference temperature T1 corresponding to 0.25 and the high reference temperature T2 corresponding to 0.75 are calculated every frame.

The gain correction value calculated by the processor 5 is stored in the third memory 6, and the offset correction value is stored in the fourth memory 7. The gain correction value stored in the third memory 6 and the offset correction value stored in the fourth memory 7 are respectively updated at a predetermined frequency (for example, 60 Hz) field rate.

On the other hand, the digital calculator 8 is a real-time digital calculator, the digital image signal stored in the second memory 4, the gain correction value stored in the third memory 6, and the offset correction stored in the fourth memory 7. A 12-bit video output signal whose values are supplied and corrected for nonuniformity by calculating at a predetermined frequency (e.g. 60 Hz) field rate using an internal multiplier 8A and an adder 8B according to the following equation (3). Occurs S).

S _i (T) = g _i V _i (T) + o _i ----------------------- (Equation 3)

In addition, the reference temperature controller 9 receives the reference temperature value from the processor 5 to precisely control the low reference temperature T1 and the high reference temperature T2 of the reference temperature source 10, and accordingly the reference temperature value. The temperature source 10 may provide reference temperatures T1 and T2 for non-uniformity correction of the focal plane array infrared detector 1 by using an internal thermoelectric cooler.

2 illustrates a method of controlling the reference temperatures T1 and T2 by using a histogram. The principle is as follows.

In order to precisely correct the nonuniformity of the focal plane array infrared detector 1 having the nonlinear time varying function, the values of the reference temperature T1 and T2 should be controlled in real time in accordance with the temperature distribution of the input image. The histogram of the thermal image has a characteristic of accurately indicating the temperature distribution. In the present invention, the reference temperature T1 and T2 are calculated from the cumulative distribution of the histogram.

That is, by analyzing the temperature distribution of the image and setting the low reference temperature (T1) corresponding to 0.25 and the high reference temperature (T2) corresponding to 0.75 as two reference values, the correction error due to the nonlinear characteristic is minimized and the time-varying function The correction error is minimized because the two reference temperatures T1 and T2 are adaptively controlled at a frame rate of 30 Hz.

As described in detail above, the present invention relates to an input image applied by controlling a reference temperature source using a histogram of an input image in a focal plane array infrared detector and adaptively correcting gains and offsets at a frame rate of a predetermined frequency. There is an effect that complete correction is performed without causing residual noise.

Claims (7)

A focal plane array infrared detector (1) for detecting an infrared image signal (IR_V) and reference temperatures (T1), (T2) and converting them into electrical signals; An A / D converter (2) for converting the analog electric signal into a digital signal; A first memory 3 for storing the digital reference temperature signal output from the A / D converter 2 and a second memory 4 for storing the image signal; A processor (5) for calculating a non-uniformity correction value and a reference temperature (T1), (T2) value based on the output signals of each of said memories (3) and (4); A third memory (6) for storing the gain correction value calculated by the processor (5) and a fourth memory (7) for storing the offset correction value; A digital calculator (8) for receiving an output value of each of the memories (4), (6), and (7) and calculating at a predetermined frequency field rate to generate an image output signal (S) of a predetermined bit with non-uniformity corrected; A reference temperature controller 9 for precisely controlling the low reference temperature T1 and the high reference temperature T2 of the reference temperature source 10 by receiving values of the reference temperatures T1 and T2 from the processor 5; ; Digital of the infrared detector comprising a reference temperature source (10) for providing a reference temperature (T1), (T2) for non-uniformity correction of the focal plane array infrared detector (1) using an internal thermoelectric cooling element Correction device. The infrared detector according to claim 1, wherein the A / D converter (2) is a high-speed A / D converter for converting an analog infrared image signal (IR_V) and a reference temperature (T1, T2) into a digital signal of 12 bits, respectively. Digital correction device. The digital correction device of an infrared detector according to claim 1, wherein each of the memories (3), (4), (6), and (7) is configured to update each stored signal at a field rate of 60 Hz. A first step of converting an analog infrared image signal and a reference temperature signal detected by a focal plane array infrared detector into a digital signal and storing the same in a memory; Obtaining a non-uniformity correction coefficient for each detection element based on a reference temperature signal of every input frame output from the memory and averaging them to obtain non-uniformity correction values; A third step of multiplying the digitally converted image signal by a gain correction value and adding an offset correction value to the resultant value to generate an image output signal S of a predetermined bit with non-uniformity corrected; Comprising a fourth step of calculating the reference temperature (T1), (T2) by using the histogram of the video signal of each input frame output from the memory, and by using this to control the reference temperature source to generate the reference temperature Digital correction method of the infrared detector, characterized in that. 5. The digital correction method of an infrared detector according to claim 4, wherein the nonuniformity correction coefficient (gi) of each detection element in said second step is obtained using the following equation. Where g _i : gain correction factor o _i : Offset adjustment factor V _i : Output voltage of the i th detection element R (T1), R (T2): Reference value for non-uniform matching at reference temperature (T1), (T2) 5. The digital correction method of an infrared detector according to claim 4, wherein when the image output signal (S) having a predetermined bit corrected for nonuniformity is calculated at a 60 Hz field rate according to the following equation. S _i (T) = g _i V _i (T) + o _i Where g _i : gain correction factor o _i : Offset adjustment factor V _i : Output voltage of the i th detection element T: Input temperature signal 5. The method of claim 4, wherein in the fourth step, the reference temperature T1 corresponds to 0.25 of the cumulative value after obtaining the cumulative distribution function from the histogram of the image, and the reference temperature T2 corresponds to 0.75 of the accumulated value. Digital correction method of the infrared detector, characterized in that the value.