What “input” means on a gate driver

“Input” refers to the driver’s logic/control pins that command switching behavior, such as: PWM (HI/LI), EN (enable), SD (shutdown), IN+/IN− (differential), and similar control channels.

This page focuses on the control-input signal path (controller → isolator (optional) → driver input), not the gate output stage or power-loop switching node.

Engineering definitions (usable on real boards)

Key take-away: differential is not “magic immunity.” It is a system: pair symmetry + reference continuity + termination discipline.

Scope boundaries (to prevent content overlap)

This page owns “input interpretation and noise survival.” Related topics are intentionally scoped to their dedicated pages:

• CMTI / dv/dt immunity: this page only points out where common-mode transients enter inputs; the definition/test method belongs to CMTI / dv/dt Immunity.
• Propagation delay & matching: this page notes that filtering/receiver choice can distort pulse width; full delay/skew budgeting belongs to Propagation Delay & Matching.
• Deadtime/interlock: this page focuses on “input glitches” that break the interlock assumption; deadtime design belongs to Deadtime & Shoot-Through Interlock.

Three field symptoms this page targets

• False turn-on/off: unexpected switching during high dv/dt transitions (often “only under load”).
• Missing pulses: short PWM commands disappear or shrink after wiring/filters/isolators.
• Non-repeatable validation: passes on bench, fails in cabinet/vehicle, or differs between labs due to measurement reference issues.

A practical taxonomy: 3 injection mechanisms + 2 amplifiers

Failure modes as symptom → likely path → fastest discriminator

Single-ended input model (SE)

A single-ended receiver compares the input pin against a local reference and decides using VIH/VIL (often with hysteresis). Over-voltage events can trigger input clamps, and even small input currents can reshape edges when the source is weak.

Practical interpretation: “logic high” is not a nominal voltage; it is a minimum margin above VIH at the driver pin relative to the driver’s local reference.

Differential input model (DIFF)

A differential receiver decides from VOD = VP − VN, while both pins must remain inside the receiver’s common-mode range (VCM). Input impedance and termination determine how reflections and asymmetry create unwanted differential error.

Practical interpretation: differential helps only when common-mode noise remains common-mode. Any asymmetry can convert it into differential spikes.

Eight datasheet fields that must be captured

• VIH / VIL requirements: defines the single-ended decision boundaries.
• Hysteresis (HYS): determines whether threshold-region noise becomes extra toggles.
• Input leakage / IIH / IIL: critical for weak drive, open-drain sources, and RC edges.
• Max input voltage + clamp behavior: indicates when over-voltage injects current or reshapes edges.
• Input capacitance (CIN): sets edge-rate loading and pulse-width distortion risk.
• VOD threshold (DIFF): minimum differential amplitude required to be interpreted correctly.
• VCM common-mode range (DIFF): hard boundary; outside this range, a receiver may saturate or misinterpret.
• Differential input impedance / termination (DIFF): dictates reflection behavior and whether external termination is required.

Engineering spec language (formula placeholders)

The following expressions define pass/fail margins without requiring a large table. Thresholds are evaluated at the driver pins.

These placeholders are meant to be populated with project-specific targets (X/Y) and verified using the validation playbook later in this page.

Pass vs risk (decision-boundary checklist)

• Pass: margins are positive (≥ X), differential common-mode stays within VCM limits, and the waveform does not repeatedly traverse the threshold region.
• Risk: margins approach zero, VCM is near a boundary, hysteresis is insufficient for observed noise, or clamp currents reshape edges and shrink pulse width.

Why differential usually helps

• Common-mode rejection: noise coupled equally onto VP and VN largely cancels in VOD.
• Decision variable is differential: the receiver triggers on VOD crossing a threshold rather than absolute voltage level.
• Pair coupling suppresses differential pickup: tightly coupled pairs tend to pick up external fields as common-mode.

These benefits require the pair to experience similar environments and similar source/termination conditions.

When differential fails (how CM becomes DM)

• Symmetry breaks: one conductor is closer to a noise source, routed differently, or sees different return conditions.
• Reference discontinuity: plane splits / slots alter field lines, making VP and VN experience different coupling.
• Pair mismatch: impedance or length mismatch creates unequal reflections, producing differential spikes.
• VCM near boundaries: common-mode excursions push the receiver into saturation/non-linear behavior.

The failure mechanism is consistent: common-mode disturbances are converted into differential error that crosses VOD_th.

Differential wins / Differential fails (fast decision cards)

Design principle: preserve symmetry so noise remains common-mode; avoid structures that manufacture differential error.

Isolator output types (PP / OD / DIFF) — what changes electrically

• Push-pull (PP): strong drive and fast edges; primary risk is overshoot/ringing causing threshold re-crossing.
• Open-drain (OD): requires external pull-up; primary risk is slow rise eating minimum pulse width and undefined state when floating.
• Differential output (DIFF): decision is based on VOD; primary risk is CM→DM conversion from asymmetry or missing termination.

Levels & thresholds: alignment rules (driver pin is the reference)

Compatibility is confirmed by comparing isolator output guarantees to driver input requirements at the driver pins (not at the controller, and not at the isolator package).

• SE link: verify VOH/VOL (after interconnect) meets VIH/VIL with margin ≥ X_V.
• DIFF link: verify VOD(min) meets VOD_th with margin ≥ X_mV and VCM stays inside VCM limits.
• Edge integrity: verify rise/fall times do not collapse minimum on/off pulse width (limit: X_ns or X_%).

Defaults & power-off behavior: avoid floating and back-powering

• No floating inputs: every input must have a defined state during normal operation and during any single-rail power loss.
• Failsafe must be measurable: when “off,” the input voltage must settle into a stable band (X to Y) with no threshold chatter.
• Back-power risk: external pull-ups or strong outputs must not inject current through input clamps beyond X_mA.

Termination & damping: when it is mandatory

• Board-to-board cable: treat as transmission line; use termination for DIFF if no internal termination is present.
• Short on-board: prefer series damping (RS) for PP/SE; full termination is rarely the first step.
• High dv/dt same board: geometry and reference continuity come first; termination cannot compensate for split-plane routing.

Practical trigger: if ringing causes multiple crossings of VIH/VIL (SE) or VOD_th (DIFF), damping/termination is required.

Connection playbook: three scenarios (3 hard rules + 1 acceptance each)

Do / Don’t rules (field-executable)

Engineering definitions (test at the driver pin)

• Delay (tPD): time shift from source edge to receiver decision point (fixed offset).
• Pulse-width distortion (ΔPW): difference between source PW and effective PW above the decision region.
• Edge conditioning: dv/dt reduction that increases time spent near the threshold region and raises sensitivity to noise.

Three common pitfalls (symptom → fastest check → fix direction)

Acceptance criteria (placeholders for review & test)

• Minimum effective pulse width: PW_eff(above threshold) ≥ X_ns at the driver input.
• Pulse-width distortion limit: |ΔPW| ≤ X_ns (or ≤ X_% for duty-based criteria).
• Post-disturb recovery: recovery ≤ Y_us with false toggles = 0 over Y-window.

Measurements are taken at the driver input pins because interconnect loading and reference behavior define the true decision waveform.

The “three-piece kit”: what each tool protects — and what it can break

• Series R (RS): damps ringing and limits injected current; can be tuned without large PW loss.
• RC filter: removes high-frequency glitches; can introduce ΔPW and swallow short pulses if over-sized.
• Clamp: limits over-voltage and injection; adds capacitance and may trigger recovery effects if misapplied.

Protect what matters: threat → preferred tool → acceptance (no tables)

Safe-state design (input-side only): OFF by default under faults

• No-float rule: any single-point fault that disconnects the signal must still force a deterministic OFF input state.
• Power sequencing rule: isolator and driver power loss must not create transient ON pulses at the receiver.
• No back-power rule: external pulls must not forward-bias input clamps beyond X_mA under any rail-off condition.

Over-filtering risk points (must be prevented)

• RC too large: PW_eff collapses and short pulses are swallowed (must meet H2-7 PW criteria).
• Clamp too capacitive: edge deformation increases ringing sensitivity and shifts decision timing.
• Injection + recovery: clamps that dump charge into the isolator/receiver can trigger saturation/recovery windows.

Measurement doctrine (avoid probe artifacts)

• Probe at the receiver: all acceptance metrics are taken at the gate-driver input pins, not at the source.
• SE reference is explicit: single-ended probing must reference driver REF/SGND to avoid ground-bounce illusions.
• DIFF requires VOD + VCM: differential probing must capture VP, VN, VOD, and VCM to separate CM from DM errors.
• No long ground leads: long ground clips form loops and can convert dv/dt fields into fake “glitches”.

Fast 10-minute debug path (each step has pass placeholders)

Symptoms → first checks (short list)

• Narrow pulses disappear: check PW_eff and RC/pull-up timing first.
• False toggles only at high dv/dt: check reference continuity and CM→DM conversion before adding filters.
• After EFT/ESD it stays unstable: check clamp injection and isolator recovery window.
• Scope looks clean but counters fail: re-validate probe reference and bandwidth; eliminate artifact paths.

Checklists (copyable into review forms)