STMicroelectronics TSC888CILT LDO Overview for Stable IoT & Industrial Power Systems
The STMicroelectronics TSC888CILT is a high-efficiency, low-dropout regulator (LDO) engineered for B2B applications that demand stable voltage output, minimal power waste, and compact design-targeted at Internet of Things (IoT) (wireless sensor nodes, portable wearables), Industrial Automation (low-power control modules, process monitoring circuits), and Consumer Electronics (smart home devices, handheld diagnostic tools). It integrates critical features-fixed 3.3V output voltage, 150mV max dropout voltage, 100mA max output current, SOT23-5 surface-mount package, and -40??C to +125??C operating temperature-to eliminate external power-filtering components and streamline energy-efficient, space-constrained power designs.
With low-dropout high-stability voltage regulation (tuned for battery-powered and industrial-grade systems), it balances consistent 3.3V output with minimal power loss and tiny PCB footprint. This makes it ideal for engineers prioritizing power efficiency (long-running wireless devices), voltage stability (critical for sensitive sensor chips), and miniaturization (sub-6mm modules) in electronic circuits. As part of STMicroelectronics?? industrial LDO lineup-a series trusted by 238,000+ developers in IoT and industrial control sectors-it meets strict quality benchmarks: RoHS 2 compliance, ISO 9001 certification, IEC 61000-6-3 EMC compliance (industrial/consumer environments), and 8,400+ hours of reliability testing (including thermal drift, load transient, and voltage ripple validation).
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Senior engineers at a leading IoT sensor brand endorse it: ??This LDO powers our wireless soil moisture sensors. The 150mV low dropout cuts battery drain by 22%, and SOT23-5 fits our 5mm x 5mm module. It??s helped us hit 99.97% device uptime and 95% customer satisfaction.?? For more energy-efficient IoT and industrial components, visit IC Manufacturer.
Technical Parameters of STMicroelectronics TSC888CILT
| Parameter | Specification |
|---|---|
| Function | Low-dropout regulator (LDO) for stable voltage regulation in power systems |
| Output Voltage | Fixed 3.3V DC (??2% tolerance at 25??C) |
| Input Voltage Range | 3.8V to 5.5V DC (compatible with 3.7V lithium-ion batteries and 5V industrial grids) |
| Max Dropout Voltage | 150mV (at 100mA output current, 25??C) |
| Max Output Current | 100mA (continuous, at 3.3V output, 25??C) |
| Quiescent Current (Typ) | 80??A (no load, 3.3V output, 25??C) |
| Output Voltage Ripple | 20??Vrms (at 1kHz frequency, 100mA load) |
| Line Regulation (Typ) | 0.2%/V (input voltage change from 3.8V to 5.5V) |
| Load Regulation (Typ) | 0.5% (load current change from 1mA to 100mA) |
| Operating Temperature Range | -40??C to +125??C (industrial/extended temperature grade) |
| Package Type | SOT23-5 (5-pin Small Outline Transistor), 2.9mm x 1.6mm x 1.1mm dimensions (surface-mount) |
| Protection Features | Overcurrent protection, thermal shutdown (activates at +150??C typ) |
| Compliance | RoHS 2 compliant, ISO 9001 certified, IEC 61000-6-3 |
Key Technical Features of TSC888CILT Low-Dropout Regulator
- 150mV Low Max Dropout Voltage: Saves power. An IoT designer noted: ??Our 3.7V battery-powered sensor uses 22% less energy-runtime extended from 9 days to 11 days, cutting field maintenance costs.??
- 80??A Low Quiescent Current: Reduces idle drain. A portable device brand shared: ??Smart home humidity sensor standby time rose by 30%-batteries last 14 days vs. 10.8 days with standard LDOs.??
- SOT23-5 Ultra-Compact Package: Saves space. An industrial control brand confirmed: ??PCB area used dropped by 58%-our power module fits in 4.7mm x 4.7mm, down from 11.2mm x 11.2mm with DIP LDOs.??
- -40??C to +125??C Temp Range: Ensures stability. An outdoor sensor brand said: ??Weather station voltage drift dropped by 74%-warranty costs saved $260,000 yearly in agricultural deployments.??
- 100mA Max Output Current: Powers multi-sensor nodes. A smart factory brand explained: ??Powers 2 temperature sensors + 1 pressure sensor simultaneously-component count cut by 1, reducing BOM costs by $0.25 per unit.??
Advantages of TSC888CILT vs. Typical Alternatives
Compared to high-dropout linear regulators (LDOs), bulky DIP-package LDOs, and low-current LDOs, the TSC888CILT solves critical B2B pain points-backed by real customer feedback:
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1. Less Power Waste Than High-Dropout LDOs: High-dropout LDOs (e.g., 400mV dropout) waste more energy from batteries, shortening runtime for wireless IoT sensors. The 150mV low dropout fixes this. An environmental IoT brand said: ??Our old 400mV dropout LDO sensor lasted 6.5 days-this 150mV model lasts 11 days. We now supply 9 city councils for air quality monitoring, expanding our market share by 32%.??
2. Smaller Footprint Than Bulky DIP-Package LDOs: DIP-package LDOs (e.g., DIP8) take up 2.7x more PCB space than SOT23-5, forcing industrial modules to exceed size limits (e.g., 7mm x 7mm). The SOT23-5 package fixes this. An industrial control brand shared: ??Our old DIP8 LDO power module was 12mm x 12mm-too big for 7mm-max enclosures. This SOT23-5 model fits, and we launched a compact controller that boosted sales by 35%.??
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3. Higher Current Than Low-Current LDOs: Low-current LDOs (e.g., 50mA max) can??t power multi-sensor nodes, requiring 2+ LDOs that add cost and space. The 100mA high current fixes this. A smart home brand confirmed: ??Our old 50mA LDO needed 2 units for a 2-sensor humidity-light node-this 100mA model uses 1. BOM costs dropped by $0.40 per unit, and we??ve secured 6 new smart home clients.??
Typical Applications of STMicroelectronics TSC888CILT
This high-efficiency LDO excels in power-critical B2B designs-proven in these key use cases:
- Internet of Things (IoT) (Wireless Soil Moisture Sensors): Low dropout extends battery life, 3.3V output powers sensor chips. An IoT brand confirmed: ??Sensor runtime up by 22%, false power-related alerts down by 41%.??
- Industrial Automation (Low-Power Control Modules): High current powers 2+ chips, compact package fits enclosures. An industrial brand reported: ??Control module size down by 58%, BOM costs down by $0.25 per unit.??
- Consumer Electronics (Smart Home Humidity Sensors): Low quiescent current saves standby power, 3.3V output matches chip requirements. A consumer brand shared: ??Sensor standby time up by 30%, battery replacement frequency cut by 28%.??
- Internet of Things (IoT) (Outdoor Weather Stations): Wide temp range resists weather, low ripple ensures stable sensor data. An IoT brand confirmed: ??Weather station voltage stability up by 74%, warranty costs saved $260,000 yearly.??
- Consumer Electronics (Portable Diagnostic Tools): Compact package fits handheld devices, overcurrent protection prevents damage. A consumer brand noted: ??Diagnostic tool size down by 58%, repair rates dropped by 33%, user satisfaction at 94%.??
Frequently Asked Questions (FAQ) About STMicroelectronics TSC888CILT
Why is 150mV max dropout voltage important for battery-powered IoT sensors?
Battery-powered IoT sensors (e.g., soil moisture) rely on limited 3.7V lithium-ion energy-high-dropout LDOs (400mV) waste more power as heat, shortening runtime. 150mV minimizes waste. An agricultural engineer said: ??Our old 400mV dropout sensor needed battery changes every 6.5 days-this 150mV model needs changes every 11 days. Farmers save 32% on battery costs, and our agricultural sensor sales rose by 31%.??
How does 80??A quiescent current improve smart home sensor standby time?
Smart home sensors spend 80% of time in standby-high-quiescent-current LDOs (200??A) drain batteries fast, requiring frequent replacements. 80??A cuts idle waste. A smart home brand said: ??Our old 200??A LDO humidity sensor lasted 10.8 days-this 80??A model lasts 14 days. Users report 28% fewer battery changes, and we??ve retained 89% of our smart home clients, up from 64% last year.??
What value does the SOT23-5 package add for industrial control modules?
Industrial control modules need to fit in 7mm x 7mm enclosures-bulky DIP8 LDOs (12mm x 12mm) are too large, forcing design compromises. The SOT23-5??s 4.7mm x 4.7mm size fixes this. An industrial brand said: ??Our old DIP8 LDO module couldn??t fit in 7mm enclosures-this SOT23-5 model fits. We added a diagnostic LED to the saved space, reducing troubleshooting time by 34%, and industrial sales improved by 35%.??
How does the -40??C to +125??C temperature range benefit outdoor weather stations?
Outdoor weather stations face -39??C winters and +93??C summers-LDOs with narrower ranges (0??C?C85??C) drift 5% in voltage, causing sensor data errors. The wide range limits drift to 1.4%. An IoT brand said: ??Our old 0??C?C85??C LDO sensor had 18% data errors in winter-this model has 5%. Meteorologists get reliable data, and weather station sales rose by 30%.??
Why is 100mA max output current useful for multi-sensor IoT nodes?
Multi-sensor IoT nodes (e.g., temp + humidity + light) need 60?C80mA total current-low-current LDOs (50mA) require 2 units, adding cost and space. 100mA powers all 3 sensors with 1 LDO. An IoT brand said: ??Our old 50mA LDO needed 2 units for a 3-sensor node-this 100mA model uses 1. BOM costs dropped by $0.40 per unit, and we??ve secured a $1.8M contract for 4,500+ nodes.??