CA1276994C - Automatic gain control in a digital signal processor - Google Patents

Abstract

AUTOMATIC GAIN CONTROL IN A DIGITAL
SIGNAL PROCESSOR

Abstract Automatic gain control in a digital signal processor is described. A predetermined threshold value, a predetermined automatic gain control value, and a predetermined count threshold value are estab-lished and stored in a data memory associated with a signal processor. Each incoming signal sample that is received is multiplied by the AGC value with the product being temporarily stored in the data memory.
The absolute value of the resulting product is taken and added to the predetermined threshold value. If the result of this operation results in a signal processor overflow, then the AGC value is reduced and stored back into the data memory. The adjustment period of the AGC value is chosen to be well under the allowable distortion time for speech, dual tone multi-frequency reception, and modem operation.

Description

A~'Y-~5-00~
. . . ~

Descri ~ `~

AUTOM~TIC ~AIN CONT~OL IN A DIGITAL

Technical Field This invention relates generallv to automatic gain control, and more particularly~ to automatic gain control in a digital signal processor.
Backqround Art The automatic adjustment of the ~ain of an incoming electrical or acoustical sianal prior to further signal processing is known in the prior art.
Typically, automatic gain control (AGC) mechanisms are implemented in hardware using non-linear devices, such as diodes, to compand the incoming siqnal. In digital si~nal processing, such non-linear devices are un-availahle. Normally, a digital signal processor accomplishes AGC by perfo~ming arithmetic division. A
- drawback with the use o~ arithmetic division is that it requires signiricant amounts of the processin~
capabilitv of the digital signal processor.
AGC mechanisms are normallv used in devices which receive amplitude varying signals. The followinq are examples of such amplitude varving signals~ speech from a microphone wherein the distance between the microphone and the speaker chan~es or where individual speakers talk at varving amplitudes; modem signal`s from a telephone line, since the amplitude attenuation of any one telephone line may be different from other telephone lines; and, speech from a telephone line wherein the sources of variation may be d-1e to both the speaker and the varving telephone line. Automatic - gain control mechanisms are helpful to limit the :

AT~ '' S-GO~ ' ~2~

dynamic range over which most of the most complex portion of the signal processing must work, i.e., to prevent amplifiers ~rom saturating from high level signals while at the same time minimizing the effects of thermal noise introduced ~y circuitry.
As mentioned previously, the non-linear effe~ts commonly employed in hardware implementations are not available in a digital signal processor. An AGC
process in such a processor uses division. Tvpicallv, the input signal le~Jel, ~7hich is usually the largest sample over a period of time, is determined, and then arithmetic inversion is performed. All su~se¢uent incoming samples over a period of time are then multiplied by this inverted value. Consequentlv, large incoming signals are multiplied bY a small AGC
value, and small incoming signals are multiplied Dy a larae AGC value. A problem with current signal processors is that division is performed rather inefficiently. As a result, large amounts of the processing po~Jer of a digital signal processor is employed just for automatic gain control. In a telephony en~ironment, this leaves critical functions such as dual tone multi-fre~uenc~ detection demodula-tion, call proqress, and telephone line monitor, ~Jithreduced processing capability.
U. S. Patent ~,191,995 sho~7s a t~tpical digital AGC circuit implemented in hardware. The circuit includes both an analoq attenuator and a digital attenuator for applying controlled attenuation to the input analog signal and the digital representation of -said input siqnal, respectivel~7. The analog and digital attenuators operate under control of a diqital ; con~rol circuit. U. S. Patent 3,996,519 also disclos-es a digital signal processor having automatic gain control implemented in hardware. The processor .

~ l Y ~
- \

disclosed therein utilizes two parity generators, a set-reset flip-flop shift register and logic to control the output of a seriallv connected shift register.
U. S. Patent 4,499,586 describes a microprocessor controlled automatic gain control used in a receiver for receiving recurrln~ first and second scanninq signals. The apparatus includes a linear and a logarithmic amplifier. Means are provided for gener-ating a diqital gain control signal in response to a peak magnitude signal with a D/A convertor for con-verting digital gain control siqnals into analog qain control signals which are then applied to the gain control input of a linear amplifier.
U. S. Patent 4,477,698 discloses an apparatus for detecting piCkUP at a remote telephone set. The apparatus uses a high gain band pass filter with no automatic gain control employed. Although the appara-tus is able to detect telephone call pickup, it isunable to compensate for different speech levels ana/or modem signal levels which would require auto-matic gain control.

2 Disclosure of the Invention - _ _ _ _ Accordingly, it is an ob~ect of this invention to provide improved automatic gain control in a digital signal processor.
Xt is another ob~ect o* this invention to provide automatic gain control in a digital sianal processor without the use of non-linear hardware devices.
In accordance with these and other ob~ects of the invention, automatic qain control is provided in a digital signal processing environment to provide automatic gain control (AGCl in speech, telephon~, and modem applications. According to the present AT9-85-00~

invention, a predetermined threshold valne is estah-lished and stored in a memorv location in the data storage associated with signal processor. A predeter-mined automatic gain control (AGC~ value as well as apredetermined count threshold value is established and also stored in the ~ata storage. Each incominq signal sample that is received is multiplied by the AGC
value, with the product being temporarily stored at another location within the data storaae of the sinal processor. The absolute value of the resultinq product is taken and added to the predetermined threshola value. If the result of this operation results in a signal processor overflow, then the AGC
value is reduced ~multiplied by a positive fraction less than one~ and stored hack into the memor~v loca-tion in ~Jhich the predetermined AGC value has been stored~ If a predetermined numher of consecutive samples causes an overflow, then the AGC value is reduced within a set time period. This time period is chosen to be well under the allo~rable distortion time ~or speech, dual tone multiple frequencv ~DTMF~
reception, and modem operatlon.

Brief Description of the Drawinq Fig. 1 is a functional block diaaram of the system according to the present invention.
Fig. 2 is a flow chart depicting the operation of the preferred embodiment of the present invention.
Fig. 3 is a flow chart depicting an alternative embodiment according to the present invention.

Best Mode for Carr~rinq Out the Invention _.. ~
A simplified functional block diaqram is sho~rn in Fig. 1. Signal processor 11 mav be an~J co~merciallv available signal processor such as the Texas AT9~~5-004 ~1.2~

Instruments TMS32010. Sianal processor 11 is totallv controlled by host processor 19 and must have its central processing unit (CPU) instructions loaded before operation. Signal processor 11 uses instr~lc-tion memory 12 as well as data memor~ 13. Both of these memories, i.e., instruction memory 12 and data memory 13 are accessible by host processor 19 althol1ah not at the same time as sig~al processor 11. Instruc-tion memor~7 12 is accessible bv host processor l9 onlywhen signal processor 11 is turned off, i.e., reset.
At that time, host processor 19 can load from instruc-tion memory 12 and then switch to data memor~7 13 which is shared at all times dynamically with signal procss-sor 11. Both signal processor 11 and host processor19 have the capabilitv to interrupt one another With ir.terrupt masking under control of host processor 19.
Speech andJor audio signals are input over lines 21, 22, and 23 to receiver 17. These signals, which have amplitude variations, may be speech from either a microphone or telephone as well as speech from a telephone line r or they mav be modem siqnals from a ; telephone line. These incomina signals, which are in analog format, are converted to digital by A/D con-verter 16 and temporarilv stored in data reqister 15.
These diqitized signals are then input to data memory 13. A/D converter 16 provides diqitized samples of the analog signals input over lines 21, 22, and 23.
It is these digitized samples which are stored in data memory 13 and which are amplitude adjustedf therebv providing automatic gain control usinq siqnal proces-sor ll.
The automatic gain control (AGG) of the siqnals stored in data memory 13 is performed bv si~nal processor 11 in con~unction ~Jith data memorv 13 usin~
bus 14. In addition to the storaqe of the digitized AT9~85-004 ~L2~

;~ ~
input samples in data memorv 13, other predetermined values which are used to perform the automatic gain control of such digitized input signals are stored in data memorv 13. These predetermined values include:
a threshold value (T~VAL~; a predetermined AGC value (AGCVAL); and, a predetermined count threshold (UPCNT~. Additionally, durina the AGC processina of the digitized samples in data memorv 13 by signal processor 11, further values are ~enerated which are then stored in data memorv 13. This will be explained in more detail hereinafter.
The automatic gain control of the di~itized samples stored in data memory 13 will now be explained in more ~etail ~7ith reference to Fig. 2. The prede-termined threshold and count-threshold values, AGCVAL
and UPCNT, respectively, are input from data memorv 13 over bus 14 to signal processor ll. The digiti~ed samples are also input over bus la from data memorv 13 2 to signal processor 11. Each digitized sample input over bus 1~ is multiplied in siqnal processor 11 bv the AGC value which had previouslv heen stored in data memorv 13. The produc~ value is then temporarilv stored in data memory 13 as PRODVAL. The absolute value of the product just formed is ~hen taken and added to the predetermined threshold value, T~VAL, which had been stored in data memory 13. If the result of this summation is an overflow, then the original AGC value is multiplied by 0.75 and stored back into data memory 13. Additionally, when an AGC
overflow occurs, a count, known as the AGC count, is reset to 0.
~ lhen an overflow condition does not occur, i.e., the sum of PRODVAL and TEVAL does not cause overflow, then the AGC count value is incremented. ~lhen a significant number of digitized samples are input to ~ . i signal processor 11 which do not cause the threshold value to overflow, then the AGC count value, which is incremented each time, can become.quite large.
Accordinglv, for each digitized sample that does not cause an over1Ow condition, the AGC count value is compared with the predetermined count threshold value, UPCNT, which had been stored previously in data memory 13. When the AGC count value e~ceeds the ori~inal count threshold value, then the AGC value is multi-plied by 1.01. For each succeedinq inputted sample time that the output threshold does not overflow, the AGC value is once again multiplied by 1.01.
The adjustment of the AGC value in the AGC count is done at a rate to insure that there is an allowable amount of distortion in the incoming signal upon which the automatic gain control is performed. For speech, the allowable distortion time is on the order of 15 milliseconds while for dual tone multi-frequency tones, the allowable distortion time is about 5 milliseconds. The allowa~le distortion time ~or modems is considerablv longer than that for sPeech.
Having assured that the AGC value is changed rapidlv enough to prevent distortion, the ~ain controlled output is then taken to be the product value that results ~y multiplying the AGC value by the digitized sample that is input to siqnal processor 11 over bus 14 from data memory 13.
~.n alternative method of performing automatic gain control on the diqi~ized samples stored in data memorv 13 will now be described in more detail ~-7ith reference to Fig. 3. This alternative method of AGC
differs from that previously described in that there are two predetermined threshold ~alues which are stored in data memory 13, threshold value 1 and threshold value 2. Threshold value 1 is ~reater than AT9-~5-004 39~

~.-. i~
threshold value 2, thereby providing a lower threshold than value 2 would provide. Usin~ this alternative method, after the AGC value has dropped to a level where the threshold value 2 no longer causes over-flows, but where threshold value 1 still does cause overflows, the amount of reduction in the AGC value at overflow is decreased. This is seen bv the addit~onal bran,ch existing in the flow chart depicting this alternative embodiment as opposed to the preferred embodiment depicted in Fi~. 2. As can be seen, the "no" branch after the first o~Terflow decision provides that the absolute value of the product value is added to a secona value for the AGC. At this point, an additional decision is made as to whether or not an overflow occurred. If the overflow occurred once again, then the AGC collnt is reset and the AGC value is multiplied by 0.97 instead of the previously used 0.75. The "no" branch follo~Tinq this second overflo~
decision path is identical to the "no" path s~o~m for the preferred embodiment. ~hat is, the AGC count is incremented and then a decision is made as to whether or not the AGC count is greater than the count thresh-old which had previously been stored in data memory 13. If the AGC count does, at this point, exceed the count threshold, then the AGC value is multiplied bv 1.01. Once again, after the AGC has been perfornted on the digitized input sample, the product value is taken as the gain controlled Outptlt of the svstem.
As an example of the operation of the alternative method, assnme that the initial AGC valne is 1,000.
Assume also that 4 Otlt of the first 23 digitized samples cause the second threshold value to be exceed-edO The AGC value will then he multiplied bv 0.75 four times bv the time the 23rd di~itized sample is reached. At that point, the AGC value is AT~-~5-oo~

76~

approximately 316. Assume further that 7 out of the next 15 samples cause the first threshold value to be exceeded but do not exceed the second threshola value.
If the multiplier associated with the first threshold value is 0.97 as sho~m in Fig. 3, then after these 15 samples, the AGC value will be 255. This iterative process allows very quick adjustment of the AGC value to the correct range.
In another alternative embodiment hased upon the preferred embodiment, a pl-lralitv of threshold values and a plurality of count threshold values are used.
In this alternative embodiment, the highest valued of the plurality of predetermined threshold values is compared to the sum of the product term and the predetermined automatic gain control value. If the ` highest value of the pluralitv of predetermined threshold values is exceeded by the sum of the product term and the predetermined automatic gain control value, then the automatic qain control ~7alue is reduced. Similarly, a pluralitv of count threshola values is established and the lo~est valued of the plurality of count threshold valtles is compared to the antomatic aain control count value. If the automatic gain control count value exceeds the 10~7est valued of the plurality of count threshold values, then the automatic gain control value is multiplied by a number greater than 1.
While the invention has been particnlarlv sho~m and descrihed with reference to a preferred and an alternative embodiment thereof, it will be understood by those skilled in the art that the foregoing and other changes in form and detail will be made therein without departing from the spirit and scope of the invention. Specifically, multiple threshold values may be used in the alternative embodiment to enable AT~ 04 9~

increased precision on the automatic gain control adjustments. Further~ the up multiplier may be made a f~nction of the threshold range within which the AGC
value is operating.

'

Claims (19)

1. A method of providing automatic gain control of input signals in a signal processor, said method comprising the steps of:
multiplying a sample of an input signal by a predetermined automatic gain control signal to form a product term, adding a predetermined threshold value to an absolute value of said product term; determining whether said addition of said absolute value of said product term and said predetermined threshold value created an overflow condition; and reducing said predetermined automatic gain control signal in response to said overflow condition.

2. The method as recited in claim 1 wherein said step of reducing comprises the step of multiplying said predetermined automatic gain control value by a constant having a value less than a value of one.

3. The method as recited in claim 2 further comprises the step of establishing a count threshold value.

4. The method as recited in claim 3 further comprises the steps of:
establishing an automatic gain control count value;
resetting said automatic gain control count value to a value of zero subsequent to said overflow condition; and incrementing said automatic gain control count value in the absence of said overflow condition occurring.

5. The method as recited in claim 4 further comprises the steps of:
comparing said automatic gain control count value to said count threshold; and increasing said automatic gain control value in response to said automatic gain control count value exceeding said count threshold value.

6. The method as recited in claim 1 further comprising the step of establishing a plurality of predetermined threshold values whereby a first predetermined threshold value is greater than a second predetermined threshold value.

7. The method as recited in claim 6 and wherein the step of adding said predetermined threshold value includes the step of adding said second predetermined threshold value to said product term.

8. The method as recited in claim 7 wherein said overflow condition is a rust overflow condition and further includes the steps of:
determining whether said addition of said absolute value of said product term and said second predetermined threshold value created said first overflow condition; and adding said absolute value of said product term to said first predetermined threshold value if said overflow condition was created.

9. The method as recited in claim 8 further includes the steps of determining whether said addition of said absolute value of said product term and said first predetermined threshold value created a second overflow condition; and reducing said predetermined automatic gain control signal in response to said second overflow condition.

10. The method as recited in claim 9 further comprises the step of establishing a count threshold value.

11. The method as recited in claim 10 further comprises the steps of:
establishing an automatic gain control count value;
resetting said automatic gain control count value to a value of zero subsequent to the occurrence of said first overflow condition or said second overflow condition; and incrementing said automatic gain control count value in the absence of said second overflow condition occurring.

12. The method as recited in claim 11 further comprises the steps of:
comparing said automatic gain control count value to said count threshold; and increasing said automatic gain control value in response to said automatic gain control count value exceeding said count threshold value.

13. An apparatus for providing automatic gain control of input signals in a signal processor, comprising:

means for multiplying a sample of an input signal by a predetermined automatic gain control signal to form a product term; means for adding a predetermined threshold value to an absolute value of said product term; means for determining whether said addition of said absolute value of said product term and said predetermined threshold value created an overflow condition; and means for reducing said predetermined automatic gain control signal in response to said overflow condition.

14. The apparatus as recited in claim 13 further comprises means for establishing a plurality of predetermined threshold values whereby a first predetermined threshold value is greater than a second predetermined threshold value.

15. The apparatus as recited in claim 13 wherein said reducing means comprises means for multiplying said predetermined automatic gain control value by a constant having a value less than a value of one.

16. The apparatus as recited in claim 15 further comprises means for establishing a count threshold value.

17. The apparatus as recited in claim 16 further comprises:
means for establishing an automatic gain control count value, means for resetting said automatic gain control count value to a value of zero subsequent to said overflow condition; and means for incrementing said automatic gain control count value in the absence of said overflow condition occurring.

18. The apparatus as recited in claim 17 further comprises:
means for comparing said automatic gain control count value to said count threshold, and means for increasing said automatic gain control value in response to said automatic gain control count value exceeding said count threshold value.

19. An apparatus for providing automatic gain control of input signals, comprises: means for establishing a predetermined automatic gain control value, means for establishing a predetermined threshold value, means for receiving a sample of an input signal and multiplying said sample by said predetermined automatic gain control value, thereby generating a product term; means for forming an absolute value of said product means for adding said absolute value of said product term to said predetermined threshold value; means for determining whether said sum of said absolute value of said product term and said predetermined threshold value resulted in an overflow condition; and means for reducing said automatic gain control value in response to said overflow condition.