Those who are familiar with Dr. Eric Bogatin’s Rule #9 will know this one. Before you do any measurement, anticipate what you expect the result to be, because that is the most important way of identifying if there is a potential problem.
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| Figure 1. A
transmitted rectangular pulse suffers distortion by the time it reaches the receiver. Broadening and reflections from previous transmitted bits add to the pulse response, creating inter-symbol interference. |
High-speed serial links such as those used in DDR4 and DDR5 are subject to a variety of signal degradation challenges. Insertion losses, frequency dependent attenuation and inter-symbol interference (ISI), as well as others, are among the most commonly encountered sources of signal degradation.
Figure 1 shows how reflections can cause ISI on a
rectangular pulse. When a rectangular pulse is transmitted, it suffers
distortion which is apparent when it reaches the receiver. It may be broadened due to group delay
dispersion because different frequency components of the signal propagate along
the signal path at differing velocities. In addition, there may be echo pulses,
due to impedance mismatches in the channel.
These mismatches cause reflections that propagate back and forth over
the channel and appear as these echoes where subsequent bits should be.
Generally, these signal losses can be compensated for using
any of several equalization techniques. The commonly used equalization
techniques are feed forward Equalization (FFE), Continuous Time Linear
Equalizations (CTLE), and Decision Feedback Equalization (DFE). FFE and CTLE basically filter the signal to
increase the amplitude of high frequency signal components eliminating the
frequency dependent attenuation of the signal path.
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| Figure 2. Example of a 4-tap DFE equalizer. |
The DQ signal goes through an analog gain adjustment stage
and is applied to a summer. The output
of the summer goes to the first slicer, implemented as a flip flop, where the
logical state (0 or 1) is determined, and the signal is delayed by one clock
cycle. The signal propagates through a
total of four such slicers. The output
of each slicer is weighted by individual tap weights T1 – T4 and is then fed
back to the summer where the weighted sum is subtracted from the DQ signal. The feedback returns the scaled copies of the
last four bits to the input. This
effectively removes ISI from the input. Since the signal is quantized and noise
component is ignored in that process it is not propagated. The clock is required to assure correct
timing of the summation components.
DDR5 specifies the use of Decision Feedback Equalization or
DFE. DFE is used rather than FFE or CTLE
because it provides equalization without increasing the noise level on the
signal. FFE and CTLE basically boost the high frequency response of the channel
to compensate for the channel’s frequency dependent attenuation. The boost is the result of an analog filtering
process. This has the effect of increasing noise and noise-like effects like
crosstalk, as well. The slicer stages in
DFE quantizes the signal ignoring the noise voltage, and it does not propagate
noise to the output of the equalizer. So, it provides high frequency boost
without the noise.
In addition to the excellent noise performance, DFE is
relatively inexpensive to implement.
The DFE equalizer has one possible negative characteristic:
if one of the slicers makes an incorrect determination, then the output will
see a burst of errors until the sequence is cleared. This is a not common event, especially if the
data sequence is random.
The DDR Debug Toolkit includes tools for setting up DFE. The
weight of each tap can be entered manually, or the DFE can be “trained”. The training process will automatically
determine and enter the correct tap weights.
To learn more about DDR testing and our DDR solutions, watch the on-demand webinar, DDR4/5 & LPDDR4/5 Probing and Debug Solutions.
Also see:
Which Virtual Probing Method to Use?
Isolating DDR Read and Write Operations
Removing Reflections from DDR Signals Probed Mid-Bus
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| Figure 1. Virtual probing methods like VP@Rcvr can help remove reflections from signals probed mid-bus. |
If the board has already been populated, there is an even greater problem because the interposer can’t be used, so probes may have to be placed in the middle of the bus in order to make a measurement. In this situation, the probe picks up signals reflected from the memory controller and the memory chip, as well as the desired signals. Reflections appear as non-monotonic ripples on the edges of DQ and DQS signals, as shown in Figure 2.
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| Figure 1. DDR DQ and DQS signals are in phase during a Read operation and out of phase during a Write operation. |
The phase relationship between the Data (DQ) signal and the
Data Strobe (DQS) signal indicates the type of operation, as shown in Figure 1.
The DQ and DQS signals are phase aligned with edges overlapping in Read mode. In Write mode, they are out of phase, and the DQS edge overlaps the center of the DQ eye. In the lower speed versions of DDR memory devices, the measuring instrument could be triggered on this phase difference, enabling the isolation of the desired operation for testing.
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| Fig. 1. Modern, slim front panel. |
In order to optimize that real estate, front panels have become increasingly slim, and many front panel controls on newer Teledyne LeCroy oscilloscopes are multiplexed, meaning they have multiple functions or can be used to control multiple on-screen objects. Here is a list of tips to keep in mind when using the front panel.
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| Fig 1. Rail droop in response to a load step is a typical case of mutual aggressors in a PDN. |
An obvious example is a load step in the PDA, where something
in the system being turned on pulls current from the VRM that supplies a rail.
In Figure 1, you can see how the output voltage of the VRM supplying a 1 V rail
droops in response to a load step before it recovers. This is still noise: it is a signal
variation that we're not expecting and don't want.
We want to be able to characterize that noise, because too much droop could affect the operation of other components that are already consuming power from that device.
In order to do so, we’re going to measure the rail transient response to the load application. We need only look at two signals: the voltage and the current on the rail of interest. Figure 1 shows the voltage on C5 (the green trace) and the current on C8 (the orange trace).
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| Figure 1. Line set to "quiet low" shows ground bounce occurring as I/O driver switches. |
Q: From what frequency should we consider ground
bounce to be a problem?
A: Ground bounce is really due to a dI/dt. Generally, it becomes a problem with rise times shorter than 100 ns. The bandwidth of this is about 3.5 MHz. This means ground bounce can be an issue at relatively low frequency.
