KR102392276B1 - Apparatus for generating dds chirp signal capable of compensation of phase shift - Google Patents

Abstract

The present invention relates to an apparatus for generating a DDS chirp signal, and more particularly, to an error due to a phase shift occurring in a frequency accumulator and a phase accumulator in the device for generating a DDS chirp signal. It relates to a device for generating a DDS chirp signal capable of compensating for
A device for generating a DDS chirp signal according to an embodiment of the present invention includes: a frequency accumulator for receiving a frequency control word (FCW) and accumulating and outputting the frequency control word; a phase accumulator receiving the output value from the frequency accumulator and accumulating and outputting the received output value from the frequency accumulator; the error compensation unit detecting a compensation value from the output of the phase accumulator and storing the detected compensation value; and a subtractor that subtracts the compensation value stored in the error compensator from the output value of the frequency accumulator and provides the subtracted value to the phase accumulator.

Description

DDS chirp signal generator capable of compensating for phase error

The present invention relates to an apparatus for generating a DDS chirp signal, and more particularly, to an error due to a phase shift occurring in a frequency accumulator and a phase accumulator in the device for generating a DDS chirp signal. It relates to a device for generating a DDS chirp signal capable of compensating for

Synthetic Aperture Radar (SAR) is an all-weather radar that acquires high-resolution images of a distant target using electromagnetic waves. The radar's range resolution improves as the signal bandwidth increases. Therefore, it should be designed so that a wide-band signal can be stably generated and transmitted/received.

SAR generates a chirp signal using a linear frequency modulation (LFM) technique in which an instantaneous frequency linearly increases with time in order to generate a wide-band signal.

Representative methods of generating a chirp signal include signal generation using a VCO, a memory map method, and a Direct Digital Synthesizer (DDS) method. Among them, DDS has advantages such as good frequency resolution and fast switching speed, and is recently spotlighted in SAR.

1 is a block diagram of a conventional DDS chirp signal generating apparatus for generating a down-up chirp signal by using the DDS.

The conventional DDS chirp signal generator shown in FIG. 1 includes a frequency accumulator (FA), a phase accumulator (PA), a look-up table (LUT), and a digital-to-analog converter (DAC). , Digital-to-Analog Converter).

In the case of generating a chirp signal using DDS, a parameter of a signal to be generated is specified, a frequency control word (FCW) corresponding thereto is inputted, and the signal is generated through the process shown in FIG. 1 .

The frequency accumulator FA accumulates and outputs the FCW at every rising edge of each system clock. Since FCW is a constant value, the frequency accumulator FA outputs a ramp-type signal.

A conventional device for generating a DDS chirp signal performs a subtraction operation by subtracting a maximum control word (CW) value from an output of the frequency accumulator FA to generate a down-up chirp signal. Through the corresponding process, the DDS chirp signal generator generates a signal having a band of -Maximum FCW/2 to Maximum FCW/2.

The output generated from the frequency accumulator FA is input to the phase accumulator PA to generate an instantaneous phase of the chirp signal. The lookup table LUT stores the amplitude signal of the sine wave compared to the phase address, and outputs a chirp signal according to the output of the phase accumulator PA.

Here, in the conventional DDS chirp signal generator, in order to input the output of the phase accumulator PA to the lookup table LUT, the output of the phase accumulator PA is unwrapped in units of 2 pi ( A truncation error occurs when unwrapping.

The cause of the truncation error is that the FCW in the form of an integer does not express the output of the frequency accumulator (FA) in the form of a quadratic function (Float) that is unwrapped in units of 2 pi. due to the inability

Due to the above-described truncation error phenomenon, an offset occurs in the output of the phase accumulator PA, and as a result, a phase shift occurs in the chirp signal generated by the conventional DDS chirp signal generator. ) occurs.

This phase shift error (Phase Shift Error) appears at the start phase of the output of the chirp signal generated by the conventional DDS chir signal generator for every pulse repetition interval (PRI).

FIG. 2 shows outputs of the frequency accumulator FA and the phase accumulator PA when the above-described truncation error is generated in the conventional DDS chirp signal generator.

As shown in (a) of FIG. 2 , in an ideal case, the frequency accumulator FA shows an output in the form of a ramp, but in the case of a general digital system, as shown in FIG. Similarly, although it is a lamp shape, it shows discrete output characteristics.

'T' in (b) of FIG. 2 means the maximum number of bits that can be stored in the register of the frequency accumulator (FA). When the register operates with n bits, the bit corresponding to 2 ^(n-1) is can be stored in registers. A bit value exceeding 'T' appears as a start offset of the next cycle of the frequency accumulator (FA). An offset occurs due to a truncation error of the frequency accumulator FA. This truncation error then affects the output of the phase accumulator PA.

FIG. 2(c) shows the output of the frequency accumulator FA after the modulo operation is performed in the modular of FIG. 1 .

FIG. 2(d) shows that the output of the frequency accumulator FA is wrapped, and an offset is applied to the output of the phase accumulator PA due to the truncation of the frequency accumulator FA. (Offset) appears. As shown in FIG. 2D , when an offset occurs and a phase shift occurs, the frequency and phase characteristics of the output chirp signal are distorted.

For this reason, when a signal having a phase shift is range-compressed, signal quality such as side lobe indicators (PSLR, ISLR) is deteriorated. Ultimately, since a phase shift error causes deterioration of radar image quality, it must be removed in order to obtain an improved radar image.

An object of the present invention is to provide an apparatus for generating a DDS chirp signal capable of compensating for an offset generated in a phase accumulator due to a cut-off phenomenon of the frequency accumulator in the apparatus for generating a DDS chirp signal.

A device for generating a DDS chirp signal according to an embodiment of the present invention includes: a frequency accumulator for receiving a frequency control word (FCW) and accumulating and outputting the frequency control word; a phase accumulator receiving the output value from the frequency accumulator and accumulating and outputting the received output value from the frequency accumulator; the error compensation unit detecting a compensation value from the output of the phase accumulator and storing the detected compensation value; and a subtractor that subtracts the compensation value stored in the error compensator from the output value of the frequency accumulator and provides the subtracted value to the phase accumulator.

When the DDS chirp signal generator according to the embodiment of the present invention is used, the offset generated by the phase accumulator can be compensated, and thus there is an advantage in that it is possible to reduce and prevent distortion of the frequency and phase characteristics of the output chirp signal. .

Furthermore, since signal quality such as an impulse response function (IRF) can be improved, there is an advantage in that a radar image of improved quality can be obtained.

1 is a block diagram of a conventional DDS chirp signal generating apparatus for generating a down-up chirp signal by using the DDS.
FIG. 2 shows outputs of the frequency accumulator FA and the phase accumulator PA when the above-described truncation error is generated in the conventional DDS chirp signal generator.
3 is a block diagram of a device for generating a DDS chirp signal according to an embodiment of the present invention.
4 is a graph for explaining the operation of the error compensator 350 shown in FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a detailed description of a preferred embodiment of the present invention is described with reference to the accompanying drawings. It should be noted that reference numerals and identical elements in the drawings are denoted by the same reference numerals as much as possible even if they are indicated in different drawings. For reference, in describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

3 is a block diagram of a device for generating a DDS chirp signal according to an embodiment of the present invention.

Referring to FIG. 3 , the apparatus for generating a DDS chrip signal according to an embodiment of the present invention includes a frequency accumulator 310 , a first subtractor 320 , a phase accumulator 340 , and an error compensator 350 .

The frequency accumulator 310 receives the frequency control word FCW as an input, accumulates the frequency control word FCW, and outputs the accumulated frequency control word FCW.

The frequency accumulator 310 accumulates and outputs the FCW at every rising edge of each system clock 304 .

The frequency accumulator 310 may accumulate and output the input FCW until the storage space of the register 313 of the frequency accumulator 310 overflows.

When the FCW input to the frequency accumulator 310 is a constant value, the frequency accumulator FA may output a signal in the form of a ramp.

The frequency accumulator 310 may include an adder 311 and a register 313 . The adder 311 adds and outputs the input FCW and the value stored in the register 313 . The register 313 stores the value output from the adder 311 , and provides the stored value to the adder 311 by feeding back the value.

The first subtractor 320 subtracts the output from the frequency accumulator 310 and the compensated output value from the error compensator 350 and outputs the subtraction operation. The first subtractor 320 subtracts the compensation value stored in the memory unit 357 of the error compensation unit 350 from the value output from the accumulator 310 and outputs the subtracted value.

The modular operation unit 360 performs a modular operation on the output value from the first subtractor 320 and outputs it. The modular operation unit 360 outputs a residual value obtained by dividing the value output from the first subtractor 320 by a preset value.

The second subtractor 325 performs a subtraction operation for subtracting the maximum control word from the output from the modulo operator 360 and outputs the subtraction operation. This is to generate a down-up chirp signal. Through this process, the apparatus for generating a DDS chirp signal according to an embodiment of the present invention may generate a chirp signal having a band of -(maximum FCW)/2 to (maximum FCW)/2.

The phase accumulator 340 accumulates and outputs the output value from the second subtractor 325 .

The phase accumulator 340 accumulates and outputs the output value from the second subtractor 325 at every rising edge of the system clock 304 .

The phase accumulator 340 may include an adder 341 and a register 343 . The adder 341 adds and outputs the value input from the second subtractor 325 and the value stored in the register 343 . The register 343 stores the value output from the adder 341 and provides the stored value to the adder 311 again.

The device for generating a DDS chirp signal according to an embodiment of the present invention provides feedback capable of storing the output of the phase accumulator 340 in a predetermined memory in order to compensate for a phase offset generated in the phase accumulator 340 . and an error compensator 350 which is a feedback loop. The apparatus for generating a DDS chirp signal according to an embodiment of the present invention having an error compensator 350 may compensate for a phase shift error included in the output of the phase accumulator 340 .

The error compensator 350 may include a phase extractor 351 , a phase wrapper 353 , a minimum value detector 355 , and a memory unit 357 . Operations of the phase extraction unit 351 , the phase wrapping unit 353 , the minimum value detection unit 355 , and the memory unit 357 will be described with reference to FIG. 4 .

3 and 4 , the phase extractor 351 extracts a phase value from the output from the phase accumulator 340 . The phase value extracted by the phase extractor 351 may be expressed as shown in (a) of FIG. 4 .

As shown in (a) of FIG. 4 , since the phase values output from the phase extractor 351 have a truncated shape every 2 pi, a process of restoring them is required.

For restoration, the phase wrapping unit 353 performs a 2 pi Wrapping operation to express the phase values output from the phase extraction unit 351 in the form of a quadratic function. A phase value as shown in FIG. 4B may be output by the phase wrapping unit 353 .

In a state in which a phase shift is generated, an offset is generated in the output value of the phase accumulator 340, and accordingly, the inflection point of the output through the wrapping operation in the phase wrapping unit 353 ( minimum) is located at a value other than 0. This position is detected through the minimum value detection unit 355 , and as shown in FIG. 4C , the minimum value may be detected by detecting an inflection point in the output value of the phase wrapping unit 353 .

The inflection point of the output of the phase wrapping unit 353 changes at every pulse repetition period PRI, and this value is deterministic according to the constant pulse repetition period PRI. Therefore, the minimum value of the inflection point of the output of the phase wrapping unit 353 is stored in the memory unit 357 and used for phase shift error compensation. Accordingly, the minimum value stored in the memory unit 357 may be referred to as a compensation value.

A subtraction operation is performed between the minimum value stored in the memory unit 357 and the output of the frequency accumulator 310 through the first subtractor 320 . The minimum value stored in the memory unit 357 is used as a compensation value for offsetting the offset included in the output of the frequency accumulator 310 .

As a result, the error compensator 350 outputs the inflection point value of the phase accumulator 340 stored in the memory unit 357 while the pulse repetition period PRI is maintained, so that the value of the inflection point input to the phase accumulator 340 is output. Offset value can be controlled. Through this control, it is possible to remove a phase shift error generated by the phase accumulator 340 , and consequently, it is possible to prevent deterioration of radar image quality.

Again, referring to FIG. 3, among the input signals, '2' 302 is an input value for generating a chirp signal in which the frequency linearly decreases with time and then linearly increases again, and the maximum CW ( The maximum control word, 303) means the maximum value that FCW can have.

The bit slicer 370 slices and outputs a preset bit from the output of the phase accumulator 340 . This is to match the number of bits that can be processed in the lookup tables 380a and 380b. The bit slicer 370 is an additional component, and as long as the output of the phase accumulator 340 can be used as it is in the lookup tables 380a and 380b, the bit slicer 370 may be omitted.

The lookup tables 380a and 380b store in advance information on amplitude values for each phase for one period of the sine wave.

The lookup tables 380a and 380b may include a cosine lookup table 380a and a sine lookup table 380b. Here, the cosine lookup table 380a and the sine lookup table 380b may function as output units that respectively output the I signal and the Q signal.

When the value (instantaneous phase) output from the phase accumulator 340 is input to the cosine lookup table 380a and the sine lookup table 380b, the cosine lookup table 380a and the sine lookup table 380b are The amplitude value corresponding to the instantaneous phase) is output. The output amplitude value is converted into an analog value by the digital-to-analog converters 390a and 390b and output.

A value output from the digital-to-analog converters 390a and 390b is used as a chirp signal.

The apparatus for generating a DDS chirp signal according to the embodiment of the present invention shown in FIG. 3 detects an offset included in the output of the phase accumulator 340 and feeds it back to the input of the phase accumulator 340 for frequency accumulation Since it includes an error compensator 350 for compensating for a truncation error included in the output of the unit 310, there is an advantage in that the frequency and phase characteristics of the output chirp signal are not distorted. Accordingly, when the output chirp signal is range-compressed, there is an advantage in that signal quality such as an impulse function (IRF) is improved. Accordingly, there is an advantage in that it is possible to acquire a radar image of improved quality.

The embodiments of the present invention have been described above with reference to the accompanying drawings, but these are merely examples and do not limit the present invention. It will be appreciated that various modifications and applications not exemplified above in the scope are possible. For example, each component specifically shown in the embodiment can be implemented by deformation|transformation. And differences related to such modifications and applications should be construed as being included in the scope of the present invention defined in the appended claims.

310: frequency accumulator
320: first subtractor
340: phase accumulator
350: error compensation unit
360: modular operation unit
370: beet slicer
380a, 380b: lookup tables
390a, 390b: digital-to-analog converters

Claims (5)

delete a frequency accumulator receiving a frequency control word (FCW) and accumulating and outputting the frequency control word;
a phase accumulator receiving the output value from the frequency accumulator and accumulating and outputting the received output value from the frequency accumulator;
an error compensator detecting a compensation value from the output of the phase accumulator and storing the detected compensation value; and
a subtractor that subtracts the compensation value stored in the error compensator from the output value of the frequency accumulator and provides the subtracted value to the phase accumulator;
The error compensation unit,
a phase extractor for extracting a phase value from the output value of the phase accumulator;
a phase wrapping unit that restores the phase values of the phase extractor in the form of a quadratic function;
a minimum value detection unit that detects an inflection point of an output of the quadratic function form of the phase wrapping unit and outputs a minimum value; and
a memory unit for storing the minimum value output by the minimum value detection unit;
wherein the minimum value stored in the memory unit is the compensation value.
a frequency accumulator receiving a frequency control word (FCW) and accumulating and outputting the frequency control word;
a phase accumulator receiving the output value from the frequency accumulator and accumulating and outputting the received output value from the frequency accumulator;
an error compensator detecting a compensation value from the output of the phase accumulator and storing the detected compensation value; and
a subtractor that subtracts the compensation value stored in the error compensator from the output value of the frequency accumulator and provides the subtracted value to the phase accumulator;
The frequency accumulator includes an adder and a register,
The adder adds the frequency control word and the value stored in the register and stores it in the register,
The output value of the frequency accumulator has a truncation error in which a bit value overflowing the storage space of the register appears as a start offset of an output of the next cycle of the frequency accumulator (FA),
wherein the compensation value compensates for the truncation error.
a frequency accumulator receiving a frequency control word (FCW) and accumulating and outputting the frequency control word;
a phase accumulator receiving the output value from the frequency accumulator and accumulating and outputting the received output value from the frequency accumulator;
an error compensator detecting a compensation value from the output of the phase accumulator and storing the detected compensation value; and
a subtractor that subtracts the compensation value stored in the error compensator from the output value of the frequency accumulator and provides the subtracted value to the phase accumulator;
The phase accumulator includes an adder and a register,
the adder adds the output value of the frequency accumulator and the value stored in the register and stores the sum in the register;
The value stored in the register is provided to the error compensating unit, DDS chirp signal generating device.
a frequency accumulator receiving a frequency control word (FCW) and accumulating and outputting the frequency control word;
a phase accumulator receiving the output value from the frequency accumulator and accumulating and outputting the received output value from the frequency accumulator;
an error compensator detecting a compensation value from the output of the phase accumulator and storing the detected compensation value;
a subtractor that subtracts the compensation value stored in the error compensator from the output value of the frequency accumulator and provides the subtracted value to the phase accumulator;
a modular operation unit for performing a modulo operation on the output value of the frequency accumulator and providing it to the phase accumulator;
a lookup table for receiving an output of the phase accumulator and outputting an amplitude value corresponding to the received output;
a bit slicer disposed between the phase accumulator and the lookup table and configured to slice the number of bits of the output of the phase accumulator such that the number of bits of the output of the phase accumulator is equal to the number of bits set in the lookup table; and
a digital-to-analog converter that converts the amplitude value output from the lookup table into an analog signal and outputs the converted signal;
Including, DDS chirp signal generating device.

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