Polycom SONAR OMNIVS500 User Manual

How to Choose an Acoustic Echo  
Canceller  
Application Note  
Polycom Installed Voice  
Business Group  
September 2004  
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Near End  
Far End  
Near speech  
XMT  
Near speech +  
Nonlinear  
echoes + distortion  
Processing  
Mic  
Distortion  
Echoes  
AEC  
RCV  
Far speech  
Speaker  
Far speech  
Figure 1: Illustration of the effects of AEC operation and room acoustics on the transmitted speech. The far speech that travels  
through the receive path is not modified as it passes through the AEC. In an echo canceller that is poorly designed, there may be  
residual echoes as well as distortion added to the near speech signal (these effects are described in detail later). This degrades  
the speech that is transmitted, so that the poor audio quality is noticed on the far end.  
Why not just use a speakerphone?  
Speakerphones are half-duplex, which means that only one person can talk at a time. The speakerphone  
determines which side is active (or louder) by comparing the signal levels on both sides. It turns off the  
other side until the louder side is finished. Once one side has “captured” the circuit, most speakerphones  
do not permit any sort of interruption. This inhibits the natural flow of conversation, especially if one party  
is long-winded.  
Acoustic Echo Cancellation vs. Line Echo Cancellation  
Acoustic echo cancellation and line echo cancellation both address similar problems, and are often based  
on the same technology. However, a line echo canceller generally cannot replace an acoustic echo  
canceller, because acoustic echo cancellation is a more difficult problem. With line echo cancellation there  
are generally only one or two reflections from  
With acoustic echo cancellation, the echo path  
telephone hybrids or impedance mismatches in the  
is complex and can vary continuously as people  
move around the room.  
telephone line. These echoes are usually delayed  
by less than 32 ms, and do not change very  
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frequently, if at all. With acoustic echo cancellation, the echo path is very complex (dozens or hundreds of  
reflections), lasts 100-200 ms, and can vary continuously during a conversation as people move around the  
room. Acoustic echo cancellers are therefore much more complicated devices. While line echo cancellers  
may have smaller price tags, they can’t perform under the conditions that acoustic echo cancellers can  
handle.  
Steps to Choosing An AEC  
Now that the need for an acoustic echo canceller is recognized, the best AEC solution for the application  
isdetermined based on the following four step selection process.  
Find AEC products with the features and form factor needed for the application. There may  
be several acceptable form factors. Even if one seems particularly suited to the application, consider  
all of them for a broad selection of price and performance.  
Eliminate products that don’t meet G.167 or the tail length requirements of the application.  
Although these two factors are necessary, they are not sufficient. However, if an AEC solution does  
not meet these requirements, it will most likely not sound very good at all, so don’t waste time  
arranging listening tests. If it does meet these requirements, further testing and evaluation should be  
done to ensure that it is appropriate for the application. When possible, find out the testing  
environment as well as the results of the G.167 testing.  
Judge audio quality and state machine performance by comparative listening. A panel of  
several people should listen to the different solutions (preferably the same people, under similar  
conditions, during a short time span). They should listen for the common problems echo cancellers may  
have, as well as overall quality.  
Choose the best solution. Weigh the performance, price, and convenience of each solution, and  
choose the one that will work best in the application.  
Step 1: Find AEC solutions with the features and form factor needed for the application.  
Features  
Certain features may be desirable for certain applications. For example, wide-bandwidth may be a  
necessity for videoconferencing or high quality audio conferencing systems. For integrated systems, the  
number and quality of microphones and speakers will be an issue. Automatic control of microphone and  
speaker levels may be desirable. A graphical user interface (perhaps through a connection to a Windows  
machine) may be needed. These kinds of features are too varied to be discussed in detail in this paper, but  
will certainly be a consideration in the selection of an echo cancellation solution.  
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Form Factor  
The form factor of the solution is very important because it determines how useful it is in an application.  
The performance of the product may not matter if its form factor makes it inconvenient or impossible to use  
in the desired application. Of course, there can usually be some flexibility in choosing a form factor.  
Licensing an algorithm or buying chipsets may both be acceptable to an OEM (although one may be more  
convenient), but a complete AEC solution would be out of the question for the OEM. (Indeed, that may be  
what the OEM is using the chipset to build!) A list of common form factors for echo cancellation follows.  
AEC for OEM’s  
Different form factors depend on the volume an OEM plans to produce. Although an off-the-shelf solution  
may be priced higher, at small volumes a total solution decreases development costs while reducing time-  
to-market. These are trade-offs to be weighed when making this choice:  
Modules are suitable for moderate to high volume products and can speed the process of moving a  
product to market. They provide full functionality and quick integration into a design. They can save a  
great deal of resources during the design process, and can provide a value-added feature to systems  
that may be used in a variety of applications.  
Chipsets are best for high to very high volume products. They allow tighter integration into a board,  
but require more effort for the board design.  
Algorithms are best for very high volume products, especially embedded applications that are  
sensitive to size and power consumption. Algorithms provide the opportunity to use the processor for  
multiple tasks. They also can be ported to other platforms. Although algorithms are the cheapest per  
unit at very high volumes, they require the most system integration work. This includes the supporting  
code, software interfacing issues, and integration with other resources.  
AEC Solutions for Integrators and End Users  
Typically, a conferencing application will require one AEC per location. Depending on the size of the room  
and other factors (such as the number of participants in each room), an AEC solution (packaged product) is  
presented in a number of forms. The typical forms are:  
AEC only (standalone AEC) - this is the least expensive to implement in a system but requires the  
integrator or customer to supply all external equipment (such as microphones, amplifiers, and speakers)  
for moving audio in and out of the product.  
AEC for medium to large rooms - these products may contain microphone inputs and record inputs /  
outputs in addition to the standard audio inputs and outputs required for AEC operation.  
AEC for videoconferencing - these products may contain multiple inputs and outputs, or incorporate  
“phone add” modules to permit the addition of a 2-wire conference (telephone call into the  
videoconference).  
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Step 2: Eliminate the products that don’t meet G.167 or the tail length needs of the application.  
It is relatively easy to determine how well an AEC cancels echoes. Most AEC products are based on the  
same algorithm: the adaptive LMS digital filter. This is a very well-defined algorithm that has been used  
for years. Since this process is well established, it is fairly easy to determine whether a manufacturer has  
done an adequate job of implementing it.  
The performance of the AEC can basically be judged by two criteria.  
First, the product must be compatible with the ITU G.167 recommendation for AEC.  
Second, the AEC must have an adequate tail length for the environment it is to be used in.  
Although these criteria are necessary, they are not sufficient to determine whether an AEC is good enough.  
There will most likely be several AEC solutions that meet these specifications. These are the specifications  
that can be compared on paper. What remains are the characteristics that can only be evaluated by  
comparative listening, and will make the most difference in how an AEC sounds.  
G.167 Compliance or Compatibility  
The ITU G.167 Recommendation for Acoustic Echo Controllers gives criteria for a number of performance  
characteristics typically listed on manufacturers’ data sheets. These include such specifications as initial  
convergence time (or rate of convergence), amount of cancellation, and bandwidth. G.167 compliance is a  
good indication that the LMS algorithm (the actual echo canceling filter) has been implemented reasonably  
well. It also means that the manufacturer has subjected the product to a series of standard tests, and that  
the specifications are most likely based on valid experimental data. This makes the selection process  
easier, because it sums up many different characteristics. Products can be eliminated easily based on  
G.167 compliance, rather than by evaluating each performance characteristic individually.  
When an echo canceller is G.167 compliant, the following specifications commonly found on data sheets  
have met the requirements of the standard in the room in which the echo canceller was tested:  
Bandwidth  
Weighted Terminal Coupling Loss (or total cancellation)  
Initial Convergence Time (or convergence rate)  
Recovery Time After Echo Path Variation  
Since most of the specifications found on data sheets are covered by G.167, it is not important to consider  
each of these specifications in detail. The manufacturer’s equipment should have already been verified to  
meet the requirements of the standard. If the product exceeds any of the requirements, this may improve  
the audio quality to some degree. This improvement, however, will not be as significant as the effects of  
the tail length and state machine. Therefore, all G.167 compliant devices should be considered equally  
until the other factors have been evaluated.  
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Room Acoustics  
G.167 testing is performed in real rooms. If the product meets the  
requirements in these rooms, it is compliant. A device that is  
G.167 compliant in one room, however, might not be compliant in  
another. This is because the acoustics of all rooms are different.  
This flexibility allows manufacturers to test their products in the  
types of rooms they were designed for and claim compliance.  
Because of differences in room  
acoustics, a device may be G.167  
compliant in one room and not  
another!  
However, this also means that the customer has the responsibility of determining whether the AEC will  
operate in his or her particular environment. An AEC solution that was designed to operate in an office may  
not work properly in a conference room. If an echo canceller were compliant in one room and not another,  
it would most likely be due to a tail length that was too short for the second room. Since tail length is not  
specified by G.167, it must be evaluated separately.  
Tail Length  
The tail length of an AEC is the length of time over which it can cancel echoes. The tail length of the echo  
canceller should meet the requirements of the room it is to be operated in. This is directly related to the  
reverberation time of the room. As the room reverberation time increases, a longer tail length will be  
needed in that room. If the reverberation time is much longer than the tail length, a significant amount of  
the echo will remain audible. However, excess tail length will not improve or degrade the performance of  
the canceller. Determine the minimum tail length requirements for an application based on the typical  
acoustics of rooms the product will be used in. Any products that do not meet or exceed that tail length  
should not be used in that application.  
There are two main factors that affect the reverberation time of a room. They are room size, and the  
materials used to construct the walls and objects in the room. Most sound is absorbed when it strikes walls  
or other surfaces. If materials are used that absorb sound well (such as carpet, curtains, or acoustic tile),  
the reverberation will die out more quickly than if the room contains mostly reflective materials (hard wood,  
glass, or plaster). If a room is small, the sound waves will bounce off the walls more frequently, and will be  
absorbed more quickly.  
The following formula is useful in determining the necessary tail length for an environment. It relates the  
tail length to the room size and the number of cancelled reflections.  
T = (N + 1) * d / c  
T is the tail length of the echo canceller  
N is the number of reflections cancelled  
d is the longest distance between walls  
c is the speed of sound (343 meters per second or 1125 feet per second at room temperature).  
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The equation assumes that both the microphone and the speaker are mounted on the same wall (which is  
the worst case in terms of the number of reflections that will be cancelled). In that case, N must be an odd  
integer because the even reflections travel away from the microphone.  
For example, consider a 10x20x30 foot conference room with very reflective surfaces that requires 5 echoes  
to be cancelled. In such a room, a tail length of 6 * 30 / 1125 = 160 ms would be needed. Figure 2 shows  
how these reflections would travel back and forth across the room.  
Mic  
Speaker  
30 '  
Figure 2: Longest Reflection Path from Speaker to Microphone for 5 Reflections  
Howling Rejection  
Howling rejection is important in cases where both parties are using hands-free communications systems.  
In these types of systems, it is very easy for the open microphones and loudspeakers to produce acoustic  
feedback, resulting in squealing tones (much like the feedback from a microphone in an auditorium). This  
obviously prevents any useful conversation from taking place. The most common way to avoid this problem  
is to implement howling rejection, typically done by shifting the frequency of the signal as it goes through  
the canceller. G.167 specifies a maximum frequency shift for howling rejection, but does not actually  
require that howling rejection be a part of an echo canceller. Generally, any AEC solution that does not  
have howling rejection should be avoided.  
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Step 3: Judge audio quality and state machine performance by comparative listening.  
Ideally, the AEC will let speech signals pass through it unharmed. This is actually the most difficult task in  
both designing and measuring the performance of an acoustic echo canceller. The real difficulty is in  
determining how the AEC sounds during double-talk, and whether it actually harms the sound quality by  
inaccurately determining whether it is in a double-talk state. The state machine determines the mode of  
the AEC and decides if it should be in double-talk, transmit, receive, or idle mode. The quality of the state  
machine has the most drastic effect on the audio quality of the system, and is what will make the most  
difference in the perceived quality between one echo canceller and another. Because the effects of the  
state machine are most noticeable with dynamic signals (such as those present during a real conversation),  
it is very difficult to quantitatively measure its performance. Consequently, the best way to evaluate the  
audio quality of an AEC is by listening to it during a real conversation.  
State machine  
State machines make the difference between a good echo canceller and a bad echo canceller.  
Unfortunately, most tests on echo cancellers are static: that is, the echo canceller remains in one state  
while the test is done. For instance, the tests for initial convergence time and total echo cancellation are  
done while the echo canceller is in receive mode. A great convergence rate does not guarantee that the  
system will be able to determine when to converge during a dynamic conversation. If the state machine is  
not robust, the other characteristics of the system will not mean much.  
The state machine in an acoustic echo canceller chooses between one of the following four states:  
receive (where only “far in” speech is present)  
transmit (where only “near in” speech is present)  
double-talk (where both far-in and near-in speech are present)  
idle (where no speech is present)  
The state machine must accurately choose between these modes for the AEC to operate properly. If it does  
not choose properly, speech may be distorted by the AEC or the canceller may go out of convergence. Since  
modes change frequently during conversations (especially when there are more than two people  
participating), state machine performance is extremely important.  
The basic factors of the state machine’s performance are  
1. The accuracy of determining the correct state  
2. Impact on the signal if the wrong state is selected  
3. How gracefully it switches between states.  
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The two most critical states of the echo canceller are receive and double-talk. The receive state is the only  
opportunity for the echo canceller to converge correctly. It is also the time when the echoes are most  
noticeable because they are not masked by speech from the other side. During the receive state, the echo  
canceller must converge rapidly and apply nonlinear processing to further reduce the echo. If the state  
machine does not detect a receive state correctly, echoes remain audible.  
Double-talk is most frequently mistaken for other states and has the most drastic effects on the sound  
quality when it is incorrectly detected. If the state machine confuses double-talk for a receive state, it may  
decide to start converging. If it does, it will try to converge to the near talker’s speech as well as the room  
response. This causes the canceller to go out of convergence. It may also apply nonlinear processing. This  
results in excessive attenuation, noisy or scratchy speech, or half-duplex behavior, depending on what  
methods of nonlinear processing are implemented.  
When the state machine switches between states, there should be no audible transition. On a poorly  
implemented state machine, there could be noticeable changes in volume level, changes in background  
noise level, or even audible clicks as the state machine changes states. These would be especially  
noticeable during the beginning and end of pauses in conversation, or even between words. The state  
machine may even transition several times between modes, making an annoying series of clicks.  
The Listening Test  
The listening test is the most important part of the evaluation of the acoustic echo canceller. It is the only  
time to evaluate the performance of the state machine, which is the most important factor for audio quality.  
The listening test environment should be taken into consideration if different echo cancellers are not all  
tested in the same location.  
The listening test is the only  
way to evaluate state  
machine performance.  
A panel of several people should be chosen to evaluate the echo  
canceller. If possible, the same people should evaluate all of the echo  
cancellers under consideration during a short period of time. These  
people should listen for the common problems listed in Table 3, as well  
as for the overall audio quality.  
The most important part of the evaluation is on the opposite end of the echo canceller (the far or remote  
end). This is where the echo would be heard in the first place and most of the echo canceller’s problems  
become evident. If the echo canceller is sold as part of a complete system (including microphones and  
speakers), some evaluation also should be done on the near end to ensure all of the audio components are  
of good quality.  
On the opposite end of the echo canceller, either a handset or another echo canceller of the same type  
should be used. A listening test should not be performed with a half-duplex speakerphone or a different  
echo canceller on the other end. Otherwise, it would not be clear which end had problems.  
Ideally, the operating environment for testing should be similar for all of the echo cancellers, since room  
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acoustics have such a large impact. If this cannot be arranged, at least consider the operating environment  
differences in each case in the final decision. If possible, listen to the room acoustics with the echo  
canceller disabled so the effects of the different rooms can be compared.  
Seven Things to Listen For  
Residual Echo. If there is excessive residual echo, the sound may have a hollow, distant quality or  
there may even be distinct audible echoes. This is especially noticeable during the receive mode, when  
there is no near speech to mask the echo. If this is due to a short tail length, the residual echo may  
sound delayed.  
Loss of Convergence. When the echo canceller loses convergence, the result is an audible residual  
echo that could be louder than an echo with no echo canceller at all. This is generally caused when  
the state machine mistakes a double-talk situation for a receive state. If this happens, the echo  
canceller begins to adapt to the near talker’s speech as well as the echo, and goes out of convergence.  
Howling. Pitched squealing noises may occur when both parties have hands-free systems with open  
speakers and mics. This is caused by either a lack of howling rejection, or howling rejection that is not  
working properly.  
Attenuated Speech During Double-talk. Noticeable changes in volume levels may occur during  
double-talk. This is caused when the state machine mistakes double-talk for a receive state, and  
applies switch loss (attenuates the near signal to reduce the residual echo level).  
Half-duplex Behavior. This is basically an extreme case of attenuated speech during double-talk. If  
one of the sides is attenuated so much as to become inaudible, then it would be impossible for them to  
interrupt the other party.  
Clipped or Noisy Speech During Double-talk. Very harsh and annoying distortion can be added to  
the speech signal when nonlinear processing (usually center clipping) is applied during double-talk.  
The speech may be distorted beyond recognition. This occurs when the state machine reports a receive  
state during double-talk.  
Audible State Transitions. Audible changes in background noise level, clicks, or changes in overall  
volume levels may be noticeable during state transitions. This may even occur between words or short  
pauses in speech. This is caused by a state machine that switches between states too abruptly, or too  
often.  
Step 4: Choose the best solution.  
At the end of the day, the initial list of echo cancellers should be narrowed down to a handful of acceptable  
solutions. Those that would have been inconvenient to use, did not meet the G.167 or tail length  
requirements of the application, or just did not sound good have been eliminated. Since all of the  
remaining solutions are acceptable, the final task is to weigh the differences in price against the  
differences in quality, convenience, level of support required, or time to market considerations. Any of  
these remaining solutions, however, should not have performance problems.  
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A Short Glossary of AEC Related Terms  
Near end The end of the connection where the echo canceller is located. This is where the echoes take  
place. Also, see far end.  
Far end The end of the connection opposite the echo canceller. The user on this end could be using a  
handset or another hands-free system. This is where the performance of the echo canceller are most  
noticeable. Also, see near end.  
Double-talk The state of the echo canceller when there is speech on both ends of the connection. This is  
the most difficult state to detect accurately, and most problems with audio quality occur during double-talk.  
Bandwidth The frequency range the canceller passes without attenuation. For narrow-band (telephone)  
applications, this is defined as 300-3000 Hz. For wide-band (videoconferencing, etc) applications this is  
defined as 50-7000 Hz.  
Initial Convergence Time The time it takes for the echo canceller to converge to a specified amount of  
cancellation. In G.167, the canceller must have an Initial Convergence Time of 1 second, and must achieve  
20 dB of cancellation within this time. Manufacturers may alternatively refer to the Convergence Rate of  
the echo canceller on their data sheet.  
Convergence Rate The rate at which the echo canceller converges when it begins to converge. This is  
measured in dB per second. In order to meet the Initial Convergence Time of G.167, an echo canceller must  
have a convergence rate of at least 20 dB/sec.  
Howling Pitched, squealing tones that occur when hands-free systems at both ends of a connection have  
open speakers and microphones. This is similar to microphone feedback in an auditorium. Howling can  
cause damage to audio components if it is not attenuated.  
Half-duplex Behavior of most speakerphones, which prevents howling and acoustic echo by only  
allowing one party to talk at a time.  
Tail length The length of the filter which cancels echoes (measured in ms). The more reverberation a  
room has, the longer the tail length will need to be.  
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Technical Support  
For support on the Vortex product line, call toll-free (USA/Canada) 888-248-4143, then select option 1, then  
option 3.  
For exclusive Integrator and Consultant focused support (through our PASS program), dial 1.408.474.2048;  
this number will get you help on video and Vortex products.  
For general technical support, dial 1.800.POLYCOM  
Polycom Installed Voice Business group Contact  
Information  
Our address is:  
9040 Roswell Road  
Suite 450  
Atlanta, GA 30350  
770-350-4140 Phone  
770-350-4142 Fax  
Copyright © 2004 Polycom, Inc.  
Polycom, the Polycom logo, and Vortex, are registered trademarks of Polycom, Inc. in the USA and various countries. All other brand names,  
product names, and trademarks are the sole property of their respective owners. Rev. 09/04.  
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