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Signal Tracing

Signal tracing is the mirror image of signal injection. Instead of manufacturing a test signal and pushing it backward through the circuit from the output, you take a signal that is genuinely present — an off-air station, a calibrated test signal from a generator connected to the antenna jack, or your own voice into a microphone — and follow it forward, stage by stage, in the same direction the equipment is designed to process it. At each stage you check whether the signal is present, at roughly the expected amplitude, and of roughly the expected shape. The stage where a clean, correct signal becomes faint, distorted, or absent is the faulty stage.

Where signal injection answers "does this stage pass a signal I put in?", signal tracing answers "what happens to the signal that is actually there?" Both techniques rely on the same chain logic from M21B, and in practice many hams move fluidly between the two depending on which is more convenient at a given point in the investigation. This lesson focuses on tracing: the tools used to "see" a signal at each test point, how to know what a healthy signal should look like, and how to read the clues in a degraded signal's shape, not just its presence or absence.

Key idea: Signal tracing follows signal flow forward, in the equipment's natural processing direction, using a real signal that is already present. Signal injection (M21C) works backward using a synthetic test signal. Use whichever fits the situation — a strong, steady real signal at the antenna in tracing, or a quiet bench with only your ears available in injection.
Block diagram of a transmitter audio and RF chain from microphone to antenna with small oscilloscope waveform thumbnails shown at each test point, the waveform collapsing in amplitude at the driver stage to show where signal tracing located the fault

Forward signal tracing through a transmit chain: the waveform is healthy through the modulator but collapses at the driver stage.

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Tracing vs. Injection

Choosing between tracing and injection is mostly a matter of what signal source and what "detector" are most convenient for the fault at hand. Signal tracing is the natural choice when a real, known-good signal source is already available and strong — a local broadcast or amateur station tuned in on a receiver, or your own voice keying a transmitter — and you have an instrument capable of "looking" at the signal at intermediate points, typically an oscilloscope (covered fully in M21G) or a simple detector probe. Signal injection is the natural choice when you do not have a convenient strong signal at the front end, or when the simplest possible "detector" — your own ears at a speaker — is all you need, which is exactly the receiver scenario covered in M21C.

Signal TracingSignal Injection
Signal sourceReal signal already present (off-air, mic, generator)Synthetic test signal you introduce
DirectionForward, following normal signal flowUsually backward, from output toward input
What you checkPresence, amplitude, and shape at each pointWhether the final output responds at all
Typical toolOscilloscope or RF/AF probeInjector pencil, function generator, or signal generator
Best suited toFaults with a strong, stable available signal; transmit-chain faultsReceiver faults with no convenient signal source; quick bench checks

Tools for Signal Tracing

An oscilloscope is the most capable and informative tool for signal tracing because it shows you the actual shape of the waveform, not just whether something is present. A flattened sine wave tells you about clipping; a sine wave riding on top of an unexpected DC offset tells you about a bias fault; visible noise or spurious oscillation riding on an otherwise clean signal tells you about instability somewhere in that stage or the one before it. Module 12 and the upcoming M21G cover scope use for this purpose in detail.

When a scope is not practical — working in a cramped chassis, or simply wanting a faster go/no-go check — a simple detector probe substitutes effectively for many tracing tasks. An RF probe is a small diode-detector circuit (typically a germanium or Schottky diode, a small filter capacitor, and sometimes a simple DC amplifier) that converts an RF or IF signal's envelope into a DC voltage your multimeter can read — effectively turning your ordinary DC voltmeter into a crude RF voltmeter. An audio probe is the AF equivalent: a small amplifier with a built-in speaker or headphone jack, often with a blocking capacitor at its input so it can be touched directly to a circuit node without disturbing DC bias, letting you literally listen at any point in an audio chain. Both tools are simple enough to build as a weekend project and are staples of any well-equipped troubleshooting bench.

Knowing What "Correct" Looks Like

Signal tracing only works if you have some reference for what a healthy reading should look like at each test point — without that, you cannot tell a degraded signal from a normal one. Three sources provide this reference, in order of reliability: a manufacturer's service manual with an alignment or voltage chart (many ham transceiver service manuals include exactly this kind of table, listing expected signal levels at named test points under specified test conditions); your own measurement on an identical, known-good unit, if you have access to one (a friend's identical radio, or notes from a previous repair); and general expectations from circuit theory and typical gain figures for that class of stage, which is the least precise but still useful as a sanity check (a single common-emitter RF amplifier stage commonly provides somewhere in the range of 10-20 dB of gain, for example, so a reading that shows no gain at all, or enormous unexpected gain, is suspicious even without an exact reference number).

Step-by-Step Tracing Procedure

  1. Establish a strong, stable input signal. Tune in a strong local station, or connect a calibrated signal generator to the antenna jack at a known, moderate level. For a transmitter, use a steady audio tone (a function generator, or simply a sustained vowel sound) into the microphone input.
  2. Start at the first accessible stage and record a baseline. Note the signal's presence, approximate amplitude, and shape at the earliest convenient test point.
  3. Move forward one stage at a time, comparing to the previous reading. At each stage, the signal should change in a predictable way — amplified, filtered, frequency-shifted, or demodulated, depending on the stage's function — but should not simply vanish or degrade unexpectedly.
  4. Identify the stage where the signal first becomes wrong. The fault lies in the stage between the last point where the signal was correct and the first point where it was not.
  5. Combine with divide-and-conquer where the chain is long. You do not have to trace every single stage in strict sequence — jumping to a midpoint test, as in M21B, then tracing forward or backward from there, is often faster on long chains.

Reading the Clues in a Degraded Signal

A signal that is simply absent narrows the fault to "something in this stage blocks signal entirely" — likely an open coupling capacitor, a dead active device, or a broken connection. But a signal that is present but wrong carries much more diagnostic information, and learning to read these clues is what separates a fast diagnosis from a slow one.

What You See on the ScopeLikely Meaning
Signal present but much weaker than expectedReduced gain in this stage — bias fault, degraded active device, or a parallel leakage path
Flat-topped or clipped waveformStage is being overdriven, or its bias point has shifted toward saturation/cutoff
Correct amplitude but wrong frequency contentA filter or tuned circuit has drifted or failed (wrong component value, cracked toroid, shifted trimmer)
Unexpected oscillation or noise riding on the signalStability problem — often a decoupling or layout issue (see Module 19 and Module 20) rather than a single failed part
DC offset shift with otherwise normal AC signalBias network fault — a resistor drifted in value or a coupling capacitor leaking
Signal present intermittentlyA marginal connection, cold solder joint, or a component failing under thermal or mechanical stress

Worked Example: Transmitter With Low RF Output

Symptom: A 100 W HF transceiver now produces only about 8 W of RF output on all bands, confirmed with a calibrated wattmeter into a dummy load. Receive performance is completely normal.

Trace point 1 (microphone input / speech amplifier output): A steady 1 kHz tone fed into the mic input produces a clean, correctly amplified audio waveform at the speech amplifier output, matching the expected amplitude noted in the service manual's alignment chart. Conclusion: speech processing is healthy.

Trace point 2 (balanced modulator / mixer output): A clean, correctly shaped SSB envelope is present at the expected IF frequency and amplitude. Conclusion: the modulator and first mixer stage are healthy.

Trace point 3 (driver stage output, before the final PA): The waveform here is present but its amplitude is roughly 60% of the level documented in the service manual's reference chart for this test point, and the envelope shows mild flat-topping on signal peaks. Conclusion: the driver stage is not delivering full, clean signal to the final amplifier — exactly enough to explain reduced (but not zero) RF output, since the final PA is simply amplifying a weaker, partially distorted input.

Further investigation: In-circuit voltage measurement (M21F) on the driver stage's bias network shows a resistor reading higher than its marked value and higher than the service manual's reference voltage at that node, consistent with a drifted (aged) resistor reducing bias current and pushing the stage toward an inefficient, partially-clipping operating point.

Result: Three trace points, taken in the natural forward direction of the transmit chain using the radio's own modulated signal, isolated a "low power" complaint — which could plausibly have been blamed on the final amplifier transistors, the antenna, or the SWR — to a single drifted resistor in the driver stage.

⚖ Experiment: Trace an Audio Signal Through a Multi-Stage Amplifier

This experiment uses an oscilloscope (or, if unavailable, an audio probe and headphones) to trace a real audio signal forward through a small multi-stage amplifier, reinforcing the forward-tracing procedure and the habit of comparing waveform shape, not just presence.

You will need:
  • A small two- or three-stage audio amplifier circuit (a simple breadboard build using two transistor stages, or a kit-style LM386 amplifier with an added preamp stage)
  • A function generator or audio signal source set to a 1 kHz sine wave at a low, safe level
  • An oscilloscope, if available; otherwise a simple audio probe with headphones
  • A breadboard and jumper wires
  1. Feed the 1 kHz signal into the amplifier's input and confirm a clean sine wave at the input test point, noting its amplitude.
  2. Move the probe forward to the output of the first stage. Confirm the signal is amplified and still a clean sine wave; record the new amplitude and calculate the voltage gain (output amplitude divided by input amplitude).
  3. Continue forward to the output of the final stage, again recording amplitude and shape.
  4. Now deliberately increase the input signal amplitude well beyond the amplifier's rated input range and observe the output waveform at the final stage — you should see clipping (flat-topping) appear.
  5. Reduce the input back to normal and confirm the clean waveform returns, demonstrating that the clipping was caused by stage overdrive, not a permanent fault.
What you should see:

Each healthy stage should show a clean, larger-amplitude sine wave at its output compared to its input, with no change in shape — only in scale. When you intentionally overdrive the amplifier, the output waveform should visibly flatten at its peaks (clipping) even though the input remains a perfect sine wave, directly demonstrating the "flat-topped waveform" clue described in the lesson and showing how a scope reveals information a simple presence/absence check would miss entirely.

Frequently Asked Questions

Do I need an oscilloscope to do signal tracing, or can I use a multimeter?

A multimeter alone can trace DC bias points and, with an AC voltage range, can give a rough reading of AF signal amplitude at accessible points, but it cannot show waveform shape. For RF and IF signals, a plain multimeter generally cannot respond fast enough at all. An RF or AF detector probe extends a multimeter's usefulness significantly, but an oscilloscope remains the most informative single tool for tracing, especially once waveform shape (not just amplitude) becomes important to the diagnosis.

What if I don't have a service manual with expected signal levels?

You can still trace effectively using relative comparisons: the signal should grow (or change in the way you would expect from each stage's function) moving forward through the chain, and a stage that produces no useful change, or an obviously wrong change, is suspect even without an exact reference number. General expectations from circuit theory, such as the typical gain of a single amplifier stage, are a reasonable substitute when no documented reference exists.

Can signal tracing find an intermittent fault?

It can, but it requires patience and sometimes gentle mechanical stress (tapping a suspect component or board area, or applying localized heat or cold) while watching the trace in real time on a scope, since an intermittent fault may not be present during a single static measurement. Watching the waveform continuously while flexing or tapping the board is often more revealing than a single snapshot measurement.

What does it mean if the waveform shape is correct but the frequency content is wrong?

This typically points to a frequency-selective component — a filter, a tuned circuit, or a crystal — rather than an active device. A drifted trimmer capacitor, a cracked toroid core, or a filter capacitor that has changed value with age are common causes, since these affect which frequencies pass through a stage without necessarily killing the signal entirely.

Test Your Knowledge

Answer the questions below to check your understanding. Every answer can be found in the lesson above.

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