optPulseMetric

Pulse response metric for optimization routines

Since R2020a

Syntax

metric = optPulseMetric(P,N,dt,B)

Description

metric = optPulseMetric(P,N,dt,B) calculates the eye height, eye width, eye area, and channel operating margin (COM) metrics at the target bit error rate (BER) level B. The function calculates these metrics from the pulse response matrix P, using the number of samples per symbol N, and the uniform sampling interval dt.

If there is no eye at the target BER level B, then the optPulseMetric function increases the BER until a positive height is realized.

The resolution of the optPulseMetric function is limited by number of samples per symbol N.

The nonreturn to zero (NRZ) eye metrics are estimated at a BER level, where both the center and maximum eye heights are reported. If the eye is not open at the target BER, the BER is increased until a measurable eye contour is found. The actual BER used is reported by the value usedBER reported in the output metric.

example

Examples

collapse all

Compare `optPulseMetric` Results to Statistical Eye Analysis

Open Live Script

Define the system exploration parameters. Set the target bit error rate (BER) to 1e-9, symbol time to 100 ps, number of samples per symbol to 16, and channel loss to 4 dB.

targetBER = 1e-9;
SymbolTime = 100e-12;
N = 16;
dBLoss = 4;

Calculate the sample interval.

dt = SymbolTime/N;

Create the channel model at the specified loss.

channelModel = serdes.ChannelLoss('Loss',dBLoss,'dt',dt,...
    'TargetFrequency',1/SymbolTime/2);

Define a CTLE System object™.

ctle = serdes.CTLE('WaveType','Impulse',...
    'SampleInterval',dt,'SymbolTime',SymbolTime,'Mode',2);

Process the channel impulse response with the CTLE System object.

impulse = ctle(channelModel.impulse);

Convert the impulse response to a pulse response.

P = impulse2pulse(impulse,N,dt);

Calculate the fast optimization pulse metric.

metric = optPulseMetric(P,N,dt,targetBER);

Obtain the result of the optPulseMetric function throughout the whole eye.

In order to do that, first find the number of complete unit intervals in the pulse response.

nUI = floor(size(P,1)/N);
prMatrixSort = sort(abs(reshape(P(1:N*nUI),N,[])).',1,'descend');

Then convert the BER into the number of largest pulse response samples to get the usedBER contour. The mean height is the first row (largest value) of the sorted pulse response. The noise is the sum of sorted pulse response's next nBER sample intervals.

nBER = floor(min(abs(log(targetBER)/log(2)),nUI-1));
meanEyeHeight = prMatrixSort(1,:);
Noise =sum (prMatrixSort(2:nBER+1,:),1);

Calculate the statistical eye and the eye metrics.

[stateye,vh,th] = pulse2stateye(P,N,2);
th2 = th*SymbolTime*1e12;
[~,~,contours,~,EHmax,~,~,~,~,EW,~,~,~,~,eyeAreas,~,COM] = ...
          serdes.utilities.calculatePAMnEye(2,targetBER, ...
          th2(1),th2(end),vh(1),vh(end),stateye);

Plot the statistical eye and the results of the optPulseMetric function.

figure,
      subplot(2,1,1)
      hold all
      imagesc(th2,vh,stateye)
      plot(th2,contours,'m:')
      title('Statistical Eye and Contour')
      axis('xy');
      si_eyecmap = serdes.utilities.SignalIntegrityColorMap;
      colormap(si_eyecmap)
      xlabel('[ps]')
      ylabel('[V]')
      ax = axis;
  
      subplot(2,1,2)
      th4 = [(0:N-1),NaN,(0:N-1)]*dt*1e12;
      plot(th4,[meanEyeHeight,NaN,-meanEyeHeight]/2,'r--',...
          th4,[meanEyeHeight-Noise,NaN,Noise-meanEyeHeight]/2,'m:')
      legend('Mean eye level','BER eye contour')
      title('Fast Optimization Pulse Metric')
      ylabel('[V]')
      xlabel('[ps]')
      axis(ax)

Figure contains 2 axes objects. Axes object 1 with title Statistical Eye and Contour, xlabel [ps], ylabel [V] contains 3 objects of type image, line. Axes object 2 with title Fast Optimization Pulse Metric, xlabel [ps], ylabel [V] contains 2 objects of type line. These objects represent Mean eye level, BER eye contour.

Compare the results of the statistical eye metrics and the fast optimization pulse metrics.

comparisonTable = table([metric.maxEyeHeight*1e3;metric.eyeWidth*1e12;...
          metric.eyeArea*1e12;metric.centerCOM; metric.usedBER], ...
          [EHmax*1e3; EW;eyeAreas; COM; targetBER],...
          'VariableNames',{'optPulseMetric','StatisticalEye'},...
          'RowNames',{'Max Eye Height (mV)','Eye Width (ps)','Eye Area [V*ps]',...
          'Center COM','BER'});
disp(comparisonTable)

                           optPulseMetric    StatisticalEye
                           ______________    ______________

    Max Eye Height (mV)        379.36            367.67    
    Eye Width (ps)              93.75            79.347    
    Eye Area [V*ps]            17.902            17.846    
    Center COM                 11.597            10.852    
    BER                         1e-09             1e-09

Input Arguments

collapse all

`P` — Pulse response
column vector

Pulse response, specified as a column vector. The pulse response vector can be calculated from the channel impulse response vector.

Data Types: double

`N` — Number of samples per symbol
real positive scalar

Number of samples per symbol, specified as a real positive scalar.

Data Types: double

`dt` — Uniform sampling interval
real positive scalar

Uniform sampling interval of the waveform, specified as a real positive scalar in seconds.

Data Types: double

`B` — Target bit error rate
real positive scalar

Target bit error rate (BER), specified as a real positive scalar.

Data Types: double

Output Arguments

collapse all

`metric` — Pulse response metrics
structure

Pulse response metrics, returned as a structure with these fields:

Field	Description
`maxEyeHeight`	Maximum height of the inner eye in the `usedBER` contour curve.
`maxMeanEyeHeight`	Mean eye level height at the maximum inner eye height position.
`maxCOM`	Channel operating margin (COM) at the maximum inner eye height position.
`eyeArea`	Area inside the `usedBER` contour.
`eyeWidth`	Eye width of the `usedBER` contour.
`centerEyeHeight`	Eye height at the center of the `usedBER` contour.
`centerMeanEyeHeight`	Mean eye level height at the center of the eye.
`centerCOM`	Channel operating margin (COM) at the center of the eye.
`usedBER`	The bit error rate (BER) level used in the metric calculation that gives the nonzero eye height.

Data Types: struct

More About

collapse all

Channel Operating Margin

The channel operating margin (COM) is a ratio between the signal and the noise [1] and is given by the equation:

$COM = 20 \log_{10} \frac{Signal}{Noise}$

optPulseMetric estimates the signal amplitude from the pulse response cursor voltage (the mean eye level height) [2]. The noise amplitude is estimated at a given BER by the sum of intersymbol interference (ISI) voltages.

References

[1] IEEE 802.3bj 93 A.

[2] Common Electrical I/O (CEI) Implementation Agreement OIF-CEI-04.0, section 16.3.10.2.

Extended Capabilities

C/C++ Code Generation
Generate C and C++ code using MATLAB® Coder™.

Version History

Introduced in R2020a

optPulseMetric

Syntax

Description

Examples

Compare optPulseMetric Results to Statistical Eye Analysis

Input Arguments

P — Pulse response column vector

N — Number of samples per symbol real positive scalar

dt — Uniform sampling interval real positive scalar

B — Target bit error rate real positive scalar

Output Arguments

metric — Pulse response metrics structure

More About

Channel Operating Margin

References

Extended Capabilities

C/C++ Code Generation Generate C and C++ code using MATLAB® Coder™.

Version History

Compare `optPulseMetric` Results to Statistical Eye Analysis

`P` — Pulse response
column vector

`N` — Number of samples per symbol
real positive scalar

`dt` — Uniform sampling interval
real positive scalar

`B` — Target bit error rate
real positive scalar

`metric` — Pulse response metrics
structure

C/C++ Code Generation
Generate C and C++ code using MATLAB® Coder™.