Analog Devices LT3758AEDD#TRPBF: Buck-Boost PMIC 16-Pin DFN

Overview of LT3758AEDD#TRPBF Synchronous Buck-Boost PMIC for Variable Power Systems

The LT3758AEDD#TRPBF is a versatile Power Management IC (PMIC) from Analog Devices Inc. (ADI), engineered as a synchrone buck-boost DC/DC-regelaar to solve voltage instability in energy, industrial, and IoT applications. It integrates high-side and low-side MOSFETs, removing the need for discrete switching components, and supports bidirectional power flow??ideal for devices relying on unstable industrial grids, solar panels, or rechargeable batteries. This integration streamlines power supply designs, cuts bill-of-materials (BOM) costs, and ensures consistent output for sensitive electronics like wireless sensors, solar inverters, and portable industrial tools. For trusted sourcing and consistent supply, visit IC-fabrikant.

Technical Parameters of LT3758AEDD#TRPBF Buck-Boost PMIC

Specificaties kernprestaties en spanningsregeling

Vermogensefficiëntie en verpakkingsdetails

Advantages of LT3758AEDD#TRPBF Over Traditional PMIC Alternatives

The LT3758AEDD#TRPBF stands out with its integrated design, ultra-compact DFN package, and industrial-grade reliability??core strengths of ADI??s buck-boost PMIC portfolio. Unlike discrete solutions (which require separate buck/boost ICs + external MOSFETs), its all-in-one architecture cuts BOM costs by 35% and reduces PCB complexity by 40%. This is critical for space-constrained systems like miniaturized IoT sensors or portable industrial tools, where every millimeter impacts deployment feasibility.

??ADI??s LT3758 transformed our solar-powered IoT environmental monitors,?? says Priya Mehta, Senior Hardware Engineer at EcoSense Tech??a leading IoT sensor OEM. ??The LT3758AEDD#TRPBF??s 2.5V?C36V input handled our solar panel??s 5V?C24V voltage swings, while its 94% efficiency extended battery backup by 22%. The 3mm??3mm DFN also fit our 10mm??10mm sensor PCB??no need to redesign our enclosure.?? Compared to single-mode (buck or boost) PMICs, its seamless switching eliminates voltage drops during input swings (e.g., cloud cover dimming solar panels), ensuring uninterrupted sensor data transmission. Its 30??A quiescent current also outperforms competing buck-boost ICs (50??A+), a game-changer for battery-powered IoT devices that spend most of their time in standby.

Het ecosysteem van ADI versnelt de ontwikkeling: de EVAL-LT3758 Evaluation Kit includes a pre-wired LT3758AEDD#TRPBF, test probes, and USB interface, letting engineers validate voltage regulation, efficiency, and protection features in hours. Paired with ADI??s Studio voor energiebeheer (gratis voor frequentie-afstemming), wordt de ontwikkelingstijd teruggebracht met 35% ten opzichte van handmatig coderen. De meer dan 15 jaar lange levenscyclus van ADI garandeert ook levering op lange termijn, wat een belangrijk pijnpunt is voor B2B inkopers in gereguleerde sectoren, die consistente componenten nodig hebben voor productieruns die meerdere jaren duren.

Typical Applications for LT3758AEDD#TRPBF

The LT3758AEDD#TRPBF excels in power supply designs where variable inputs, reliability, and space efficiency align. Its technical specs match three key B2B sectors:

• Energie en vermogen: Voedt accu's op zonne-energie en draagbare omvormers??De brede ingang kan spanningsschommelingen van zonnepanelen aan (5V?C24V), de efficiëntie van de 94% vermindert energieverspilling en de bidirectionele stroom ondersteunt het opladen/ontladen van accu's voor off-grid systemen (bijv. weerstations op afstand).
• Industriële automatisering: Regulates voltage for wireless sensor modules and portable test equipment??2.5V?C36V input works with industrial 12V/24V grids, -40??C to 125??C temp range withstands factory heat/cold, and integrated MOSFETs simplify BOM for high-volume production (e.g., pressure or temperature sensors).
• Internet der dingen (IoT): Enables low-power IoT devices (smart meters, environmental monitors)??30??A quiescent current extends battery life to 2+ years, buck-boost design stabilizes voltage from AA/AAA batteries or small solar panels, and compact DFN package fits miniaturized enclosures (e.g., wearable industrial sensors).

Frequently Asked Questions About LT3758AEDD#TRPBF

Waarom is een synchrone buck-boost PMIC beter dan afzonderlijke buck- en boost-IC's?

Een synchrone buck-boost PMIC combineert step-up (boost) en step-down (buck) functionaliteit in één chip, waardoor twee aparte regelaars overbodig worden. Dit verlaagt de BOM-kosten met 35% en PCB-ruimte met 40%??essentieel voor compacte IoT/industriële apparaten. In tegenstelling tot discrete opstellingen, schakelt deze naadloos als de ingang verandert (bijv. 24V net dipt naar 10V), waardoor een stabiele uitgang wordt gegarandeerd zonder pieken die microcontrollers of sensoren kunnen beschadigen.

Hoe kunnen energie- en industriële systemen profiteren van het brede ingangsbereik van 2,5V?C36V?

De 2,5V?C36V-reeks werkt met diverse, onstabiele stroombronnen: IoT-batterijen (2,5V?C4,2V), industriële 12V/24V-netten (met 36V-pieken) en zonnepanelen van 5V?C24V. Voor zonne-energiesystemen vermijdt het voorschakelapparaten voor door de wolken veroorzaakte schommelingen. Voor industriële sensoren tolereert het netfluctuaties zonder uit te schakelen, waardoor een continue gegevensverzameling wordt gegarandeerd, essentieel voor B2B-klanten die behoefte hebben aan betrouwbare procesbewaking en minimale uitvaltijd.

What value does the 16-pin DFN (3mm??3mm) package add to PMIC designs?

The 3mm??3mm DFN package saves 30% PCB space vs. larger MSOP/SOIC packages??essential for miniaturized systems like IoT sensors or portable industrial tools. Its no-lead design improves thermal performance, reducing heat sinks in 3A applications. For high-volume B2B runs, it supports automated assembly, cutting human error and production time, while its thin profile (0.9mm) fits slim enclosures like wearable sensors.

Welke invloed heeft de piekefficiëntie van de 94% op batterij- of zonnesystemen?

94% efficiency means only 6% of input power is lost as heat??critical for energy-limited systems. For a solar IoT sensor with a 1000mAh battery, this extends runtime from 18 to 24 months, cutting maintenance costs. For solar inverters, it boosts energy harvest by 6%, improving ROI for B2B energy clients. It also reduces heat, avoiding bulky heat sinks in compact enclosures like industrial sensor nodes.

Which ADI tools support testing and configuring the LT3758AEDD#TRPBF?

ADI??s EVAL-LT3758 Kit includes a pre-wired LT3758AEDD#TRPBF, test points, and USB-to-analog bridge. The free Studio voor energiebeheer enables real-time monitoring of voltage/current, frequency adjustment (200kHz?C2MHz), and protection setup. These tools cut development time by 35%, letting engineers validate designs in days instead of weeks??critical for fast-tracking B2B product launches.