Anti-saturation integrator and method

Abstract

A perfect integrator emulator includes a first multiplier multiplying an input with a first constant, KNEW, and generating a scaled input, a summer summing the scaled input with a previously generated scaled output and generating an accumulated output, a delay adding a predetermined amount of delay to the accumulated output and generating a delayed output, a second multiplier multiplying the delayed output with a second constant, KOLD, and generating the scaled output. The constants KNEW and KOLD are chosen such that the accumulated output emulates a perfect integrator's relative weighting, and saturation protection is guaranteed.

Description

TECHNICAL FIELD OF THE INVENTION

This invention is related in general to the field of digital signal processing, and more particularly, to an anti-saturation integrator and method.

BACKGROUND OF THE INVENTION

The Viterbi decoder or the Viterbi decoding algorithm are widely used for efficient coding in digital communication systems. The Viterbi decoder performs maximum likelihood decoding and involves calculating a measure of similarity or distance between the received signal and all the code trellis paths entering each state. The Viterbi algorithm removes trellis paths that are not likely to be candidates for the maximum likelihood choices. Therefore, the Viterbi aims to choose the code word with the maximum likelihood metric or stated another way, the code word with the minimum distance metric. The computation involves accumulating the distance metrics along a path using a perfect integrator.

Referring to FIG. 1 , a Viterbi decoder circuit or algorithm portion 10 includes distance calculators 12 - 1 , 12 - 2 , to 12 -N which compute the distance or difference of the received symbol from expected symbols 1 through N. The resultant computed distance from each calculator is then summed with the previous sum. The perfect integrator essentially implements an infinite accumulation for an infinite number of bits. Because a realistic implementation has a finite amount of memory and resources, the resultant accumulated sum inevitably overflows which is a condition know as saturation. When saturation occurs, the solution becomes corrupted and useless. Therefore, is a requirement of every Viterbi decoder or decoding algorithm to protect against saturation.

Conventional anti-saturation solutions check each accumulated sum at each iteration (blocks 20 - 1 , 20 - 2 , and 20 -N) to determine whether the accumulated sum is about to overflow. If yes, the metrics are scaled down by the same value to avoid saturation (blocks 26 - 1 , 26 - 2 , and 26 -N). An alternative conventional method involves scaling or normalizing all metrics for every input symbol so that the most likely metric is always zero. Yet a third conventional method uses floating point implementation rather than fixed point implementation.

All the above-mentioned anti-saturation techniques suffer from several undesirable disadvantages. These conventional methods slow down the computation speed, use more hardware in the implementation, are more costly, and use more power to operate. Further, the floating point implementation is still at risk for saturation albeit at a decrease rate than the fixed point implementation.

SUMMARY OF THE INVENTION

It has been recognized that it is desirable to protect a Viterbi decoder or algorithm from overflow, since such anti-saturation conditions are inevitable in the normal course of operation and would lead to a corrupted output.

In one embodiment of the invention, a perfect integrator emulator includes a first multiplier for multiplying an input with a first constant, K NEW , and generating a scaled input, a summer for summing the scaled input with a scaled previous output and generating an accumulated output, a delay adding a predetermined amount of delay to the accumulated output and generating a delayed output, a second multiplier for multiplying the delayed output with a second constant, K OLD , and generating the scaled previous output. The constants K NEW and K OLD are chosen such that the accumulated output does not overflow and the integrity of the viterbi decode function is not compromised.

In another embodiment of the invention, a method for emulating a perfect integrator includes the steps of multiplying an input with a first constant, K NEW , and generating a scaled input, summing the scaled input with a previously generated scaled output and generating an accumulated output, adding a predetermined amount of delay to the accumulated output and generating a delayed output, multiplying the delayed output with a second constant, K OLD , and generating the scaled previous output, and whereby the constants K NEW and K OLD are chosen such that the accumulated output does not overflow and the integrity of the viterbi decode function is not compromised.

In yet another embodiment of the invention, an anti-saturation Viterbi decoder having an integrator that includes a first multiplier for multiplying a distance input with a first constant, K NEW , and generating a scaled distance input, a summer for summing the scaled distance input with a scaled previous distance output and generating an accumulated distance output, a delay adding a predetermined amount of delay to the accumulated distance output and generating a delayed distance output, a second multiplier for multiplying the delayed distance output with a second constant, K OLD , and generating the scaled previous distance output. The constants K NEW and K OLD are chosen such that the accumulated distance output does not overflow and the integrity of the viterbi decode function is not compromised.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the present invention, reference may be made to the accompanying drawings, in which:

FIG. 1 is a simplified block diagram of a conventional portion of a Viterbi decoder including an integrator used for matched distance decay accumulation;

FIG. 2 is a block diagram of a perfect integrator emulator used for matched distance decay accumulation according to the teachings of the present invention;

FIG. 3 is a distance delay plot comparing a perfect integrator with the perfect integrator emulator of the present invention using specific K NEW and K OLD values; and

FIG. 4 is a theoretical bit rate error (BER) curve plot comparing a perfect integrator and emulated perfect integrator using various specific K NEW and K OLD values.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 2 is a block diagram of a perfect integrator emulator 40 used for matched distance decay accumulation according to the teachings of the present invention. Perfect integrator emulator 40 strives to emulate the properties of a perfect integrator. Perfect integrator emulator 40 receives as input the distance calculated between the received symbol and an expected symbol. The distance input is first multiplied with a first predetermined scaling constant, K NEW , by a first multiplier 42 and the resultant product is a scaled distance value 43 , which is provided to a summer 42 . Summer 42 sums scaled distance value 43 with a scaled old or previous distance value 45 from the output of a second multiplier 48 . Second multiplier 48 multiplies a second predetermined scaling constant, K OLD , with the previous distance 49 from the output of a delay circuit 46 . The input to delay circuit 46 is the new distance or the accumulated distance 52 .

According to the teachings of the present invention, the new distance sum may be computed by: $$ NEW ⁡ [ N ] = ( N N + 1 ) ⁢ OLD + ( 1 N + 1 ) ⁢ DISTANCE

The constants (N/N+1) and (1/N+1) preferably describe the function of the perfect integrator. The perfect integrator weighs the old and distance values for each successive iteration. The weighting of each component may be described individually: $$ OLD ⁡ [ N ] = ( N N + 1 ) ⁢ OLD $$ DISTANCE ⁡ [ N ] = ( 1 N + 1 ) ⁢ DISTANCE

Therefore the key to the distance decay anti-saturation function is that the K NEW and K OLD constants are selected such that the overall effect emulates a perfect integrator's relative weighting. It is shown below that the invention contemplates K NEW =0.01 and K OLD =0.99, which allows circuit 40 shown in FIG. 2 to emulate a perfect integrator. With carefully chosen scalar constant values such as K NEW =0.01 and K OLD =0.99, saturation will not occur and a perfect integrator's relative weighting is still emulated.

FIG. 3 is a distance decay plot comparing a perfect integrator with the emulated perfect integrator of the present invention using specific K NEW and K OLD values. It may be seen that with K NEW =0.01 and K OLD =0.99 (curve marked with □ symbol), circuit or algorithm 40 most closely emulates a perfect integrator (curve marked with A symbol). The third curve uses K NEW =0.1 and K OLD =0.9 (curve marked with ⋄ symbol), which yields an undesirable result far different from the perfect integrator.

FIG. 4 is a theoretical bit rate error (BER) curve plot comparing a perfect integrator (curve marked with x) and integrators using various specific K NEW and K OLD values. This plot shows how significant degradation occurs for improperly chosen K NEW and K OLD constants. It may be seen that for K NEW =0.01 and K OLD =0.99 (curve marked with Δ symbol), with symbol-noise distance, there is very little degradation when compared with the perfect integrator's floating point implementation. However, for constant pairs (K NEW , K OLD )=( 0.1, 0.9), (0.2, 0.8 ), and (0.99, 0.01) (curves with *, &Circlesolid;, and ♦ respectively), very significant degradation is observed. Degradation at this scale indicates a virtually non-functioning Viterbi decoder and algorithm.

The foregoing illustrates the importance that K NEW and K OLD constants be carefully selected such that the effect on the distance decay emulates the perfect integrator's distance decay curve. Employing the present invention, a Viterbi decoder or algorithm is now protected from saturation.

Although several embodiments of the present invention and its advantages have been described in detail, it should be understood that mutations, changes, substitutions, transformations, modifications, variations, and alterations can be made therein without departing from the teachings of the present invention, the spirit and scope of the invention being set forth by the appended claims.

Claims

1. An anti-saturation integrator programmed with a first constant, KNEW, selected to provide a non-overflow or underflow accumulated output of the integrator and further programmed with a second constant, KOLD, selected to provide a non-overflow or underflow accumulated output for operation of the integrator without overflow or underflow, comprising:a multiplier/summer receiving an input signal, the first constant, KNEW, and a previously generated scaled output for generating a non-overflow or underflow accumulated output; and a delay/multiplier receiving the accumulated output and the second constant, KOLD, for generating the scaled output to be applied to the multiplier/summer as the previously generated scaled output.

2. The anti-saturation integrator as set forth in claim 1, wherein the multiplier/summer comprises:a first multiplier for multiplying the input signal with the first constant; and a summer responsive to the output of the first multiplier and the previously generated scaled output for generating the non-overflow or underflow accumulated output.

3. The anti-saturation integrator as set forth in claim 2, wherein the delay/multiplier comprises:a delay adding a predetermined amount of delay to the accumulated output and generating a delayed output; and a second multiplier for multiplying the delayed output with the second constant and generating the scaled output.

4. A method for emulating an anti-saturation integrator, comprising:programming the anti-saturation integrator with a first constant, KNEW, selected to provide a non-overflow or underflow accumulated output of the integrator; programming the anti-saturation integrator with a second constant, KOLD, selected to provide a non-overflow or underflow accumulated output for operation of the integrator without overflow or underflow; receiving an input signal, the first constant, KNEW, and a previously generated scaled output to generate a non-overflow or underflow accumulated output; and receiving the accumulated output and the second constant, KOLD, to generate the scaled output identified as the previously identified scaled output.

5. The method as set forth in claim 4, wherein programming the anti-saturation integrator with a first constant comprises selecting the first constant, KNEW, equal to 0.01.

6. The method as set forth in claim 5, wherein programming the anti-saturation integrator with a second constant comprises selecting the second constant to equal 0.99.

7. The method as set forth in claim 4 wherein the input signal comprises a distance between the value of a received signal and the value of an expected signal and the accumulated output comprises an accumulated distance output, the method further comprising: NEW⁡[N]=(NN+1)⁢OLD+(1N+1)⁢DISTANCE;where NEW [N] equals the accumulated distance output; (NN+1)⁢OLDis a scaled previous distance output; and (1N+1)⁢DISTANCEequals a distance input; (N/N+1) equals KOLD; and (1/N+1) equals KNEW.