This page focuses on constant-current boost LED drivers covering open/short detection, line & temperature compensation, and PWM/analog dimming—taking you from first-pass sizing to validation and BOM hand-off.
Intro — Why Boost + Constant Current
Choose a boost + constant-current architecture when Vf_sum > VIN and you need stable luminous flux across bin/temperature variations. The current loop maintains LED current while boost provides the voltage headroom for strings and wiring loss—enabling deep dimming with loop stability.
- Scope: open/short detection (OVP/CS), line & temperature compensation (VIN feed-forward, NTC fold-back), PWM/analog dimming (or hybrid).
- Why boost + CC: simpler current matching for series strings, sub-1% dimming potential, and more predictable loop behavior at low duty.
- Focus: practical sizing → layout/EMI hints → validation matrix, without crossing into Buck or Buck-Boost pages.
VIN(min/max), strings×Vf@T, ILED, dimming range, efficiency, EMI.
D, VOUT & OVP, inductor/diode(or SR), Rsense, seed compensation.
VIN/VOUT limits, VCS, fSW, PWM/analog, NTC/line comp, protections, package, AEC-Q100.
Start/stop, deep dimming linearity, open/short, cold-start, EMI pre-scan, thermal.
Submit small-batch BOM for a 48h cross-brand recommendation.
Principle — Current Loop & Boost Power Stage
The power train is a boost (L, Q, D/SR, COUT) feeding a series LED string and a sense resistor (high-side or low-side). The sense signal is amplified into an error amplifier with compensation that modulates duty. Interfaces include PWM/EN gating, analog ADJ, NTC for thermal fold-back, and VIN feed-forward for line compensation. OVP/UVLO/CS supervise abnormal conditions.
In normal operation the current loop dominates: ILED tracks the set-point. Under open-LED or very light load the system transitions to voltage limiting (OVP) to prevent runaway. Short or heavy faults rely on peak current limit and secondary OCP with hiccup/retry or latch.
D ≈ 1 − VIN/VOUT, with VOUT ≈ ΣVf + margins (rectifier, sense, OVP).
ΔIL = (VIN · D)/(L · fSW); keep peak below saturation; choose CCM/DCM boundary per loss vs ripple.
Rs = VCS/ILED; lower VCS improves efficiency but tightens noise/ADC requirements.
Architecture — Blocks & Interfaces
The block diagram below highlights the boost power path and all control/diagnostic interfaces for a constant-current LED driver: power components, open/short detection, and hooks for PWM/analog dimming plus line/temperature compensation.
Power Path
VIN → L → Q → D/SR → COUT → LED string → Rsense. Keep high-di/dt loop tight and return currents short.
Sense & Protection
- Open-LED: FB over-voltage clamps VOUT; retry or latch per IC.
- Short: CS/OCP limits peak; optional hiccup with cool-down delay.
Control Interfaces
- PWM dimming: duty → brightness mapping; 200 Hz–20 kHz typical; use hybrid bias for deep dimming.
- Analog dimming: 0–1.2/2.0/3.3 V ranges; add input RC and route away from SW node.
- Line/Temp comp: VIN feed-forward for line; NTC fold-back for temperature.
Design & Sizing — Engineering Recipe
Use the cards below to capture targets, compute first-pass values, and apply stability and layout rules before lab validation.
Design Targets & Bounds
VIN(min/max), strings×Vf@temperature, ILED, dimming range, efficiency/thermal/EMI goals.
D ≈ 1 − VIN/VOUT; VOUT ≈ ΣVf + margins (rectifier, sense, OVP). Leave ≥10–15% headroom at VIN(min).
ΔIL = (VIN · D)/(L · fSW). Choose L so peak < saturation; target ΔIL/Iavg ≈ 30–50% for efficiency vs ripple.
Rs = VCS/ILED with VCS ≈ 50–250 mV. Lower VCS boosts efficiency but tightens noise immunity.
VRRM ≥ VOUT; check IF/IRMS and recovery. SR trades reverse losses for conduction/drive losses—validate thermals.
Set dividers for open-LED protection and startup control. Verify VOUT does not overshoot during open-string events.
EA + RC network to place zero near power pole; ensure loop remains stable under PWM gating and low-duty operation.
Line & Temperature Compensation
- Line: VIN feed-forward or proportional trim to suppress ILED drift with VIN changes.
- Temp: NTC fold-back (linear or segmented). Define start-temp, slope, and current limit.
Dimming Implementation
- PWM: 200 Hz–20 kHz; manage jitter for EMI vs audible noise; linearize duty→luminance.
- Analog: 0–1.2/2.0/3.3 V ranges; add input RC; avoid conflict with loop compensation.
- Hybrid: add small analog bias to maintain loop when PWM duty is extremely low.
EMI & Layout
- Minimize L-Q-D-C loop area; short, wide traces for switching currents.
- Star or single-point ground; split analog and power returns.
- Kelvin sense on Rsense; route dividers/NTC away from SW node.
Validation Hooks
Verify start/stop, deep dimming linearity, open/short behavior, cold-start, EMI pre-scan, and thermal margins before committing the BOM.
Protections & Diagnostics
This section outlines open-circuit, short-circuit/overcurrent, over-temperature, and UVLO/OVP behaviors, including retry/latch logic and automotive conditions such as cold crank and load dump.
Open-LED Detection
- FB threshold → OVP action; clamp VOUT during open string.
- Retry or latch based on IC; add timer to avoid audible pulsing.
- Cable disconnect: check VOUT rise slope vs OVP timer.
Short / Overcurrent
- Peak CS limit → secondary OCP; optional hiccup with cool-down.
- Differentiate wire short vs LED short by VOUT trajectory.
- Validate current-sense filtering and blanking windows.
Over-Temperature
- OTP threshold with hysteresis; shutdown above limit.
- Thermal fold-back via ADJ/NTC; coordinate with analog dimming.
- Place NTC near hot spot; ensure copper thermal spread.
UVLO / OVP
- Set UVLO thresholds and hysteresis for stable start/stop.
- OVP divider to limit VOUT under open-LED and load dump.
- Check divider power and absolute ratings.
Automotive Notes
- Cold crank: verify ILED regulation at VIN sag.
- Load dump: confirm VOUT clamp and device derating.
- Consider AEC-Q100 and thermal derating across ambient.
| Item | Trigger | Action | Hold / Retry | Recovery | Notes |
|---|---|---|---|---|---|
| Open-LED | FB > OVP threshold | Clamp/disable switching | Timer-based hiccup | Auto or EN toggle | Cable disconnect case |
| Short / OCP | CS peak limit | Current limit / shutdown | Hiccup with cool-down | Auto-retry | Wire vs LED short signature |
| OTP | TJ > OTP threshold | Fold-back / shutdown | Hold until TJ < TH−hys | Auto-recover | NTC location matters |
| UVLO | VIN < UVLO | Disable converter | Until VIN > UVLO+Hys | Auto-restart | Avoid chatter with hysteresis |
| OVP / Load Dump | VOUT > OVP or surge | Clamp / shutdown | Timer / latch per IC | EN toggle or power-cycle | Check divider power rating |
Validation & Test Matrix
Plan and record efficiency, thermal, current accuracy & ripple, start/stop, and dimming linearity & depth, then stress corners and EMI/immunity before reliability runs.
Baseline Tests
- Efficiency vs VIN/ILED/Temp; thermal mapping (Q, D/SR, L, Rsense, Cout, IC).
- LED current accuracy & ripple; start/stop overshoot; soft-start profile.
- Dimming linearity & deep dimming at low duty.
Corners & Abnormal
- VIN(min), low-temp Vf, max string count, long-cable drop.
- Open/short events; verify OVP/CS behavior and recovery.
- Cold crank, load dump (if automotive).
EMI & Immunity
- Conducted/radiated pre-scan; layout and filter iterations.
- PWM frequency impact on EMI and audible noise.
- Ground bounce probing; instrument bandwidth discipline.
Reliability & Life
- NTC curve validation; thermal cycling; ambient sweeps.
- LED Vf aging drift; long-run ILED stability.
- Component derating audit.
| Item | Condition | Spec / Target | Instrument | Waveform / Record | P/F | Notes |
|---|---|---|---|---|---|---|
| Efficiency | VIN(min/typ/max), ILED points | ≥ target at each point | Power analyzer | Table + plot | Ambient sweep | |
| Thermal | Steady-state @ worst loss | ΔT within derating | IR camera/thermocouples | Thermal map | Hot spot locations | |
| ILED accuracy & ripple | Nominal & corners | ±x% / ripple < y% | Scope + shunt/amp | ILED waveform | Bandwidth settings | |
| Start/Stop behavior | No load / full load | No overshoot/undershoot | Scope | VOUT, ILED, COMP | Soft-start tuning | |
| Dimming linearity | PWM sweep / Analog sweep | R² ≥ target | Photometer + scope | Luminance vs duty/V | Hybrid bias if needed | |
| VIN(min) corner | Min input / max ILED | Regulation maintained | PSU + scope | ILED, CS | Feed-forward check | |
| Low-temp Vf corner | Chamber low-T | Start & regulate OK | Chamber + scope | Start waveforms | Soft-start margin | |
| Long cable drop | Added series R/wire | Brightness within x% | Meter + scope | V at LEDs | Line comp efficacy | |
| Open / Short events | Inject faults | Per protection map | Scope + timer | OVP clamp, CS limit | Link to protections | |
| EMI pre-scan | CISPR bands | Below limit | EMI receiver | Plots & fixes | PWM freq sensitivity |
IC Selector — Seven Brands (Placeholder for later official verification)
Use these brand cards and tables to shortlist LED constant-current boost driver families. Columns cover: VIN range, VOUT max / OVP, ILED range, VCS, fSW, dimming (PWM/Analog/Hybrid), NTC & line feed-forward, protections (Open/Short/OTP/OCP/UVLO), package, and AEC-Q100. All entries are placeholders to be verified against official datasheets.
Texas Instruments (TI)
Series placeholder
BoostLEDDriver series placeholder (supports PWM/Analog, NTC, OVP). Text mirrors your Chinese prompt as English placeholder.
| Series / PN | VIN | VOUT / OVP | ILED | VCS | fSW | Dimming | NTC/Line | Protections | Package | AEC |
|---|---|---|---|---|---|---|---|---|---|---|
| TI-BoostLED-PL1 | 3–36V | ≤ 60V / OVP | 5–250mA | 100mV | 200k–2MHz | PWM / Analog / Hybrid | NTC + FF | Open/Short/OTP/OCP/UVLO | QFN | Opt. |
| TI-BoostLED-PL2 | 4.5–28V | ≤ 48V / OVP | 50–1000mA | 150mV | 400k–1.2MHz | PWM / Analog | NTC | Open/Short/OTP/OCP/UVLO | TSSOP/QFN | Yes* |
STMicroelectronics (ST)
Series placeholder
BoostLEDDriver placeholder series.
| Series / PN | VIN | VOUT / OVP | ILED | VCS | fSW | Dimming | NTC/Line | Protections | Package | AEC |
|---|---|---|---|---|---|---|---|---|---|---|
| ST-BoostLED-PL1 | 4–36V | ≤ 55V / OVP | 50–500mA | 100mV | 250k–1MHz | PWM/Analog | FF | Open/Short/OTP/OCP/UVLO | QFN | — |
| ST-BoostLED-PL2 | 6–28V | ≤ 48V / OVP | 100–1500mA | 150mV | 400k–1.2MHz | PWM | NTC | Open/Short/OTP/OCP/UVLO | TSSOP/QFN | Yes* |
NXP
Automotive LED series placeholder
Vehicle lighting oriented constant-current boost placeholders.
| Series / PN | VIN | VOUT / OVP | ILED | VCS | fSW | Dimming | NTC/Line | Protections | Package | AEC |
|---|---|---|---|---|---|---|---|---|---|---|
| NXP-AutoLED-PL1 | 5–40V | ≤ 60V / OVP | 100–1500mA | 100mV | 300k–800k | PWM / Hybrid | NTC + FF | Open/Short/OTP/OCP/UVLO | QFN/HTSSOP | Yes |
| NXP-AutoLED-PL2 | 6–28V | ≤ 80V / OVP | 50–800mA | 150mV | 2MHz | PWM | NTC | Open/Short/OTP/OCP/UVLO | QFN | Yes* |
Renesas
Boost backlight/lighting series placeholder
Series placeholder text.
| Series / PN | VIN | VOUT / OVP | ILED | VCS | fSW | Dimming | NTC/Line | Protections | Package | AEC |
|---|---|---|---|---|---|---|---|---|---|---|
| Ren-BoostLED-PL1 | 2.7–24V | ≤ 40V / OVP | 10–300mA | 50mV | 1–2MHz | Analog / PWM | FF | Open/Short/OTP/OCP/UVLO | WLCSP/QFN | — |
| Ren-BoostLED-PL2 | 4–36V | ≤ 50V / OVP | 50–1000mA | 100mV | 400k–1.2MHz | PWM | NTC + FF | Open/Short/OTP/OCP/UVLO | QFN | Opt. |
onsemi
NCP/NCV* Boost LED series placeholder
Placeholder; to be verified from official docs.
| Series / PN | VIN | VOUT / OVP | ILED | VCS | fSW | Dimming | NTC/Line | Protections | Package | AEC |
|---|---|---|---|---|---|---|---|---|---|---|
| ON-NCP-BoostLED-PL1 | 6–40V | ≤ 80V / OVP | 100–1500mA | 100mV | 300k–1MHz | PWM / Hybrid | NTC | Open/Short/OTP/OCP/UVLO | QFN/DFN | Yes |
| ON-NCV-BoostLED-PL2 | 4.5–28V | ≤ 60V / OVP | 50–800mA | 150mV | 2MHz | PWM | FF | Open/Short/OTP/OCP/UVLO | QFN/TSSOP | Yes* |
Microchip
HV/MCP* LED series placeholder
Placeholder; verify on Microchip website later.
| Series / PN | VIN | VOUT / OVP | ILED | VCS | fSW | Dimming | NTC/Line | Protections | Package | AEC |
|---|---|---|---|---|---|---|---|---|---|---|
| MCHP-HVLED-PL1 | 90–265VAC (front-end) / 12–24V DC | ≤ 80V / OVP | 10–500mA | 100mV | 100k–1MHz | PWM / Analog | NTC | Open/Short/OTP/OCP/UVLO | SOIC/QFN | — |
| MCP-BoostLED-PL2 | 4.5–28V | ≤ 60V / OVP | 50–1000mA | 150mV | 2MHz | PWM | FF | Open/Short/OTP/OCP/UVLO | DFN/QFN | Opt. |
Melexis
Lighting control / interface placeholders
May serve as companion/control ICs around the boost CC loop.
| Series / PN | VIN | VOUT / OVP | ILED | VCS | fSW | Dimming | NTC/Line | Protections | Package | AEC |
|---|---|---|---|---|---|---|---|---|---|---|
| Melexis-Lighting-PL1 | 5–28V | — | — | — | — | PWM / Control | NTC (if used) | Control-side | QFN | Yes* |
| Melexis-Interface-PL2 | 5–18V | — | — | — | — | Interface | — | — | QFN/TSSOP | Yes* |
Verification & Next Steps
All entries on this page are placeholders to avoid misquoting specs prior to official verification. Once part numbers are confirmed against vendor datasheets, we will populate the tables accordingly.
Engineering FAQ — LED Constant-Current Boost
Collapsible Q&A covering deep dimming, protections, line/temperature compensation, startup sequencing, sensing choices, system tips, and automotive edges. See also design, protections, and validation.
PWM dimming below 1% without loop instability?
Use hybrid dimming: bias a small analog current (≈2–5% ILED) and gate with high-frequency PWM so the controller never idles at zero. Keep PWM ≥2–5 kHz to move flicker and audible content away; freeze/slow the integrator during off-time. Validate transient response and minimum on-time at the DCM/CCM boundary.
How to avoid OVP hiccup during open-LED events?
Set OVP slightly above nominal VOUT plus diode/sense margins, then implement timer-based soft shutdown instead of immediate restart. Add a controlled bleed to discharge the output safely. Rate the divider for open-LED voltage and consider EN latch only where mandated by safety or diagnostics.
Short protection and cross-string fault discrimination?
Combine fast peak-current limit with blanking and a slower average-current/OCP comparator. Distinguish wire short from LED short by VOUT trajectory: near-instant collapse versus gradual deviation. Prefer hiccup with cool-down; reserve latch for safety. Record retry counts in validation to reveal oscillatory faults.
What PWM frequency balances audible noise and EMI?
Choose 2–20 kHz depending on magnetics and mechanical resonance; stay above 2 kHz for flicker and avoid local acoustic peaks. For EMI, offset the PWM rate from switching frequency harmonics and enable small jitter. Validate conducted/radiated scans with both minimum and maximum duty cycles.
Interaction between analog dimming and loop compensation?
Filter the ADJ node just enough to reject noise without throttling bandwidth; keep its zero/pole outside the current-loop crossover. Avoid double-integrating: the error amplifier remains dominant. At very low ADJ, add a floor or hybrid bias to preserve loop authority and sensing signal-to-noise.
How does line feed-forward counter VIN-induced ILED drift?
Sense VIN and proportionally bias the control reference so duty changes are pre-compensated. Start with a first-order coefficient from small-signal modeling, then trim using two-point calibration at VIN(min) and VIN(max). Re-check under cable drop and cold-crank profiles if applicable.
Thermal fold-back with NTC: linear or segmented mapping?
Use segmented mapping: constant current up to T1, gentle slope to T2, then strong reduction until shutdown. This protects LEDs and magnetics while preserving brightness in normal range. Place the NTC near the hot spot and validate thermal lag during rapid ambient steps.
Startup sequencing: boost first or current loop first?
Pre-charge the output with soft-start boost, then hand off to the current loop once the sense signal is reliable. Gate dimming until soft-start ends to avoid false OVP/CS trips. Cold starts demand longer soft-start and verified minimum duty to overcome elevated Vf.
Risks of choosing Rsense too small or too large?
Too small increases noise susceptibility and amplifier offset impact; thermal sense becomes coarse. Too large wastes power and heats nearby parts. Pick Rs = VCS/ILED that meets efficiency and ADC/noise budgets; Kelvin-route its traces and keep high-dv/dt nodes away.
High-side vs low-side sensing: EMC and protection impact?
High-side sense preserves ground integrity and simplifies short-to-ground detection but needs a higher-CM amplifier. Low-side offers simpler sensing and better noise margin but can disturb ground reference and short diagnostics. Choose based on layout constraints, protection thresholds, and companion interfaces.
Driving multiple parallel LED strings with one controller?
Use per-string ballast (small series resistors) or active balancing with current sinks. Provide open-string detection and degrade gracefully by redistributing current within safe limits. Keep wiring symmetry, match LEDs thermally, and define a fault policy that avoids sudden brightness jumps.
Cold start or low-temperature Vf causing no-light?
Increase soft-start ramp and ensure minimum duty exceeds the threshold needed to overcome elevated Vf. Verify OVP margins at cold, and consider pre-charge or short pre-bias of the LED string. Validate start under worst-case VIN(min), lowest ambient, and longest cable drop.
Brightness mismatch due to long cable voltage drop?
Estimate drop using wire resistance and current, then compensate with line feed-forward or remote-sense near the LEDs. Keep the return path low-impedance and avoid common ground with switching currents. Consider local regulation or current sinks when strings diverge significantly in length.
Synchronous rectification in boost LED: benefits and traps?
SR improves efficiency at high current and low VOUT margin, but risks reverse conduction and instability at light load or PWM off-time. Use robust zero-current detection and disable SR during dimming off-windows. Validate thermal and EMI behavior across duty extremes.
Automotive cold-crank and load-dump: V/I trajectory and OVP?
For cold-crank, guarantee regulation or graceful dim during VIN sag using feed-forward and soft-start shaping. For load-dump, clamp VOUT and respect absolute ratings with OVP and surge components. Define clear recovery policy (auto-retry vs latch) consistent with diagnostic requirements.
