Title: SIASmaart School
1Dual-Channel FFT Analyzers A Presentation
Prepared for AES-LA Chapter
2Presenter
- Jamie Anderson
- SIA Product Manager
- Jamie_at_SIASoft.com
SIA Software Company, Inc One Main
Street Whitinsville, MA 01588 508.234.9877 www.sia
soft.com
3Any idiot can get squiggly line to appear on an
analyzer screen. Our goal is to make ones we
can make decisions on.
Remember Computers do what we tell them to do,
not what we want them to do.
4To use an analyzer, we must first
- Verify that we are making our measurements
properly. - Verify that it is an appropriate measurement for
our purpose.
5An analyzer is only a tool YOU make the
decisions
- You decide what to measure.
- You decide which measurements to use.
- You decide what the resulting data means.
- And you decide what to do about it.
6Example
- The speaker you are measuring has a relatively
flat response except - HF is 6 dB lower than LF above 1.6 kHz
- Substantial HF noise
6dB
0dB
1k
2k
4k
8k
500
250
125
-6dB
7Example
Potential Solutions
- The speaker you are measuring has a relatively
flat response except - HF is 6 dB lower than LF above 1.6 kHz
- Substantial HF noise
EQ
Bring up HF on EQ Add extra HF to program
material
6dB
0dB
1k
2k
4k
8k
500
250
125
-6dB
8Example
Potential Solutions
- The speaker you are measuring has a relatively
flat response except - HF is 6 dB lower than LF above 1.6 kHz
- Substantial HF noise
Level
Turn up HF on Amp Turn up HF at X-over output
6dB
0dB
1k
2k
4k
8k
500
250
125
-6dB
9Example
Potential Solutions
- The speaker you are measuring has a relatively
flat response except - HF is 6 dB lower than LF above 1.6 kHz
- Substantial HF noise
System Maintenance
Loss of 6 dB and in crease in HF noise a good
indication of a bad cable on X-over HF out.
6dB
0dB
1k
2k
4k
8k
500
250
125
-6dB
10Our goal is to fix our systemnot the trace on
the screen.
11Question How can a X00 piece of software be as
accurate as a XX,000 analyzer?
12What makes an analyzer?
- Mathematical engine
- Interface
- Hardware
- Engineer
13Fast Fourier TransformsOur Friend the FFT
14The Fourier Transform
- Jean Baptiste Joseph Fourier
- All complex waves are composed of a combination
of simple sine waves of varying amplitudes and
frequencies
Amp vs Time to
Amp vs Freq
Waveform to
Spectrum
15Transforms
- A transform converts our data from one domain
(view) to another. - Same data
- Is reversible via Inverse Transform
- Yields complex data Magnitude and Phase
information
Amp vs Time to
Amp vs Freq
Waveform to
Spectrum
16FFT Resolution
- Reciprocal Bandwidth FR1/TC
- Frequency Resolution 1/Time Constant
- Larger Time Window
- Higher Resolution
- Slower (Longer time window and more data to
crunch) - Smaller Time Window
- Lower Resolution
- Faster
- Time Constant Sample Rate x FFT Length
- Decimation Varying SR FFT to get constant
res.
17FFT Resolution
- FFTs yield linear data
- Constant bandwidth instead of constant Q
- FFT data must be banded to yield
fractional-octave data. - FFT must be windowed
- FFTs assume data is continuous repeating so
wave form must begin and end at 0. - Windows are amplitude functions on data
18FFT Data Windows
19Math You Need
250 Hz T 4 ms
100 Hz T 10 ms
T .1 ms 10 kHz
T .1 ms 10 kHz
20 Hz T 50 ms
T 1 ms 1 kHz
T .5 ms 2 kHz
500 Hz T 2 ms
20Systems
Input
Output
System
Note These systems can be anything from a
single piece of wire to a multi-channel sound
system with electrical, acoustic and
electro-acoustic elements, as well as wired and
wireless connections. And remember, it only
takes one bad cable to turn a 1,000,000 sound
system into an AM radio!
21Measurement Types
- Analyzers are our tools for finding problems
- Different measurements are good for finding
different problems
22Measurement Types Single Channel vs.
Dual Channel
A()
B()
H()
- Single Channel Absolute
- Dual Channel Relative - In vs Out
Input Signal A () Output Signal B()
Frequency Response H() B()/A()
23Measurement TypesSingle Channel
- SPL VU
- Wave Form
- Amplitude vs. Time
- Spectrum
- Amplitude vs. Frequency
24Measurement Types Dual Channel
- Transfer Function Frequency Response
- Phase vs. Frequency
- Magnitude vs Frequency
- Impulse Response
- Magnitude vs Time
- Echo structure
25Transfer Function
System
Output Signal
Input Signal
Measurement Channel (RTA)
Transfer Function
Reference Channel (RTA)
26Transfer Function
System
Output Signal
Input Signal
Measurement Channel (RTA)
Transfer Function
Reference Channel (RTA)
27Transfer Function
System
Output Signal
Input Signal
Measurement Channel (RTA)
Transfer Function
Reference Channel (RTA)
28What do you get if you transform a transfer
function?
- IFT produces impulse response
- Transfer Function . . . To . . . Impulse Response
- So . . . If Frequency Response can be measured
source independently - so can Impulse Response
29 Dual-Channel FFT Issues
System
Output Signal
Input Signal
- Window Length vs Resolution
- FR 1/TC Source Independence
- Propagation Time
- Linearity
- Noise
- Averaging
- Coherence
30How Dual-Channel FFT Analyzers Work
System
Input
Output
Measurement Signal
Reference Signal
Wave
31How Dual-Channel FFT Analyzers Work
System
Input
Output
FFT
Spectrograph
RTA
FFT
Wave
RTA
32How Dual-Channel FFT Analyzers Work
System
Input
Output
FFT
FFT
Transfer Function (Frequency Resp.)
Wave
RTA
33How Dual-Channel FFT Analyzers Work
System
Input
Output
FFT
IFT
FFT
Transfer Function (Frequency Resp.)
Impulse Resp.
Wave
RTA
34Basic Measurement Set-up
Loudspeaker Room
Source
EQ / Processor
Amplifier
Microphone
Computer w/ Stereo line-level input
Mixer
35Basic Measurement Set-up
EQ/Processor Control
Loudspeaker Room
Source
EQ / Processor
Amplifier
Control Data
Microphone
Computer w/ Stereo line-level input
Mixer
36System EngineeringThe Serenity Prayer . . .
- Grant me the SerenityTo accept the things I
cannot change - Courage to change the things I can,
- And Wisdom to know the difference.
37(No Transcript)