Datasheet Linear Technology LTC3855 — Даташит

Производитель	Linear Technology
Серия	LTC3855

Двойной, многофазный синхронный контроллер постоянного / постоянного тока с дифференциальным дистанционным датчиком

Datasheets

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PDF, 2.2 Мб, Язык: анг., Файл закачен: 23 сен 2017, Страниц: 44
Dual, Multiphase Synchronous DC/DC Controller with Differential Remote Sense

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Цены

Купить LTC3855 на РадиоЛоцман.Цены — от 10 до 1 095 ₽ 45 предложений от 24 поставщиков IC: PMIC; преобразователь DC/DC; Uвх: 4,5÷38ВDC; Uвых: 0,6÷12,5ВDC
EIS Components Весь мир	LTC3855EUJ#PBF Analog Devices	252 ₽
IC Home Весь мир	LTC3855EFE#TRPBF Analog Devices	443 ₽
МосЧип Россия	LTC3855EUJTRPBF	по запросу
ЭлектроПласт- Екатеринбург Россия	LTC3855IFE#TRPBF Linear Technology	по запросу

Корпус / Упаковка / Маркировка

	LTC3855EFE#PBF	LTC3855EFE#TRPBF	LTC3855EUJ#PBF	LTC3855EUJ#TRPBF	LTC3855IFE#PBF	LTC3855IFE#TRPBF	LTC3855IUJ#PBF	LTC3855IUJ#TRPBF
N	1	2	3	4	5	6	7	8
Корпус	TSSOP-38 Габаритный чертеж корпуса	TSSOP-38 Габаритный чертеж корпуса	6x6 QFN-40 Габаритный чертеж корпуса	6x6 QFN-40 Габаритный чертеж корпуса	TSSOP-38 Габаритный чертеж корпуса	TSSOP-38 Габаритный чертеж корпуса	6x6 QFN-40 Габаритный чертеж корпуса	6x6 QFN-40 Габаритный чертеж корпуса
Код корпуса	FE	FE	UJ	UJ	FE	FE	UJ	UJ
Индекс корпуса	05-08-1772	05-08-1772	05-08-1728	05-08-1728	05-08-1772	05-08-1772	05-08-1728	05-08-1728
Количество выводов	38	38	40	40	38	38	40	40

Параметры

Parameters / Models	LTC3855EFE#PBF	LTC3855EFE#TRPBF	LTC3855EUJ#PBF	LTC3855EUJ#TRPBF	LTC3855IFE#PBF	LTC3855IFE#TRPBF	LTC3855IUJ#PBF	LTC3855IUJ#TRPBF
Архитектура	Constant Frequency Current Mode	Constant Frequency Current Mode	Constant Frequency Current Mode	Constant Frequency Current Mode	Constant Frequency Current Mode	Constant Frequency Current Mode	Constant Frequency Current Mode	Constant Frequency Current Mode
Demo Boards	DC1441A,DC1586A,DC1617A-A,DC1617A-B	DC1441A,DC1586A,DC1617A-A,DC1617A-B	DC1441A,DC1586A,DC1617A-A,DC1617A-B	DC1441A,DC1586A,DC1617A-A,DC1617A-B	DC1441A,DC1586A,DC1617A-A,DC1617A-B	DC1441A,DC1586A,DC1617A-A,DC1617A-B	DC1441A,DC1586A,DC1617A-A,DC1617A-B	DC1441A,DC1586A,DC1617A-A,DC1617A-B
Design Tools	LTspice File,LTpowerCAD File	LTspice File,LTpowerCAD File	LTspice File,LTpowerCAD File	LTspice File,LTpowerCAD File	LTspice File,LTpowerCAD File	LTspice File,LTpowerCAD File	LTspice File,LTpowerCAD File	LTspice File,LTpowerCAD File
Экспортный контроль	нет	нет	нет	нет	нет	нет	нет	нет
Основные особенности	Differential Remote Sense, PolyPhase, DCR Current Sense, Tracking, External Synchronization	Differential Remote Sense, PolyPhase, DCR Current Sense, Tracking, External Synchronization	Differential Remote Sense, PolyPhase, DCR Current Sense, Tracking, External Synchronization	Differential Remote Sense, PolyPhase, DCR Current Sense, Tracking, External Synchronization	Differential Remote Sense, PolyPhase, DCR Current Sense, Tracking, External Synchronization	Differential Remote Sense, PolyPhase, DCR Current Sense, Tracking, External Synchronization	Differential Remote Sense, PolyPhase, DCR Current Sense, Tracking, External Synchronization	Differential Remote Sense, PolyPhase, DCR Current Sense, Tracking, External Synchronization
Тактовая частота, kHz	770	770	770	770	770	770	770	770
Frequency Sync Range	250kHz - 770kHz	250kHz - 770kHz	250kHz - 770kHz	250kHz - 770kHz	250kHz - 770kHz	250kHz - 770kHz	250kHz - 770kHz	250kHz - 770kHz
Integrated Inductor	нет	нет	нет	нет	нет	нет	нет	нет
Ishutdown, мкА	30	30	30	30	30	30	30	30
Isupply, мА	3.5	3.5	3.5	3.5	3.5	3.5	3.5	3.5
Max Phases	2, 3, 4, 6, 12	2, 3, 4, 6, 12	2, 3, 4, 6, 12	2, 3, 4, 6, 12	2, 3, 4, 6, 12	2, 3, 4, 6, 12	2, 3, 4, 6, 12	2, 3, 4, 6, 12
Monolithic	нет	нет	нет	нет	нет	нет	нет	нет
Количество выходов	2	2	2	2	2	2	2	2
Рабочий диапазон температур, °C	от 0 до 85	от 0 до 85	от 0 до 85	от 0 до 85	от -40 до 85	от -40 до 85	от -40 до 85	от -40 до 85
Выходной ток, A	30	30	30	30	30	30	30	30
Output Current 2, A	30	30	30	30	30	30	30	30
Polyphase	да	да	да	да	да	да	да	да
Sense Resistor	Rsense, DCR	Rsense, DCR	Rsense, DCR	Rsense, DCR	Rsense, DCR	Rsense, DCR	Rsense, DCR	Rsense, DCR
Switch Current, A	30	30	30	30	30	30	30	30
Switch Current 2, A	30	30	30	30	30	30	30	30
Synchronous	да	да	да	да	да	да	да	да
Topology	Buck	Buck	Buck	Buck	Buck	Buck	Buck	Buck
Topology 1	Buck	Buck	Buck	Buck	Buck	Buck	Buck	Buck
Topology 2	Buck	Buck	Buck	Buck	Buck	Buck	Buck	Buck
Vin Max, В	38	38	38	38	38	38	38	38
Vin Min, В	4.5	4.5	4.5	4.5	4.5	4.5	4.5	4.5
Vout Max, В	12.5	12.5	12.5	12.5	12.5	12.5	12.5	12.5
Vout Maximum	12.5V	12.5V	12.5V	12.5V	12.5V	12.5V	12.5V	12.5V
Vout Min, В	0.6	0.6	0.6	0.6	0.6	0.6	0.6	0.6
Vout Min 2, В	0.6	0.6	0.6	0.6	0.6	0.6	0.6	0.6
Vref Accuracy Over Temp, %	0.75	0.75	0.75	0.75	0.75	0.75	0.75	0.75

Экологический статус

	LTC3855EFE#PBF	LTC3855EFE#TRPBF	LTC3855EUJ#PBF	LTC3855EUJ#TRPBF	LTC3855IFE#PBF	LTC3855IFE#TRPBF	LTC3855IUJ#PBF	LTC3855IUJ#TRPBF
RoHS	Совместим	Совместим	Совместим	Совместим	Совместим	Совместим	Совместим	Совместим

Application Notes

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PCB Layout Considerations for Non-Isolated Switching Power Supplies &mdash AN136
PDF, 215 Кб, Файл опубликован: 20 сен 2012
The best news when you power up a prototype supply board for the very first time is when it not only works, but also runs quiet and cool. Unfortunately, this does not always happen. A common problem of switching power supplies is “unstable” switching waveforms. Sometimes, waveform jittering is so pronounced that audible noise can be heard from the magnetic components. If the problem is related to the printed circuit board (PCB) layout, identifying the cause can be difficult. This is why proper PCB layout at the early stage of a switching supply design is very critical. Its importance cannot be overstated.
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Application Note 136
June 2012
PCB Layout Considerations for Non-Isolated Switching
Power Supplies
Henry J. Zhang
Introduction
The best news when you power up a prototype supply board
for the very first time is when it not only works, but also
runs quiet and cool. Unfortunately, this does not always
happen. A common problem of switching power supplies
is вЂњunstableвЂќ switching waveforms. Sometimes, waveform
jittering is so pronounced that audible noise can be heard
from the magnetic components. If the problem is related
to the printed circuit board (PCB) layout, identifying the
cause can be difficult. This is why proper PCB layout at
the early stage of a switching supply design is very critical.
Its importance cannot be overstated.
The power supply designer is the person who best understands the technical details and functional requirements of
the supply within the final product. He or she should work
closely with the PCB layout designer on the critical supply
layout from the beginning. A good layout design optimizes
supply efficiency, alleviates thermal stress, and most importantly, minimizes the noise and interactions among traces
and components. To achieve these, it is important for the …
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Modeling and Loop Compensation Design of Switching Mode Power Supplies &mdash AN149
PDF, 1.4 Мб, Файл опубликован: 23 мар 2015
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Application Note 149
January 2015
Modeling and Loop Compensation Design of
Switching Mode Power Supplies
Henry J. Zhang
Introduction Identifying The Problem TodayвЂ™s electronic systems are becoming more and more
complex, with an increasing number of power rails and
supplies. To achieve optimum power solution density,
reliability and cost, often system designers need to design
their own power solutions, instead of just using commercial power supply bricks. Designing and optimizing high
performance switching mode power supplies is becoming
a more frequent and challenging task. A well-designed switching mode power supply (SMPS)
must be quiet, both electrically and acoustically. An undercompensated system may result in unstable operations.
Typical symptoms of an unstable power supply include:
audible noise from the magnetic components or ceramic
capacitors, jittering in the switching waveforms, oscillation
of output voltage, overheating of power FETs and so on. Power supply loop compensation design is usually
viewed as a difficult task, especially for inexperienced
supply designers. Practical compensation design typically
involves numerous iterations on the value adjustment
of the compensation components. This is not only time
consuming, but is also inaccurate in a complicated
system whose supply bandwidth and stability margin …

Design Notes

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Dual Output Step-Down Controller Produces Accurate, Efficient and Reliable High Current Rails &mdash DN478
PDF, 84 Кб, Файл опубликован: 23 мар 2010
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Dual Output Step-Down Controller Produces 10% Accurate,
Efficient and Reliable High Current Rails вЂ“ Design Note 478
Mike Shriver and Theo Phillips
Introduction
The LTC В®3855 makes it possible to generate high current rails with the accuracy and efficiency to satisfy the
most demanding requirements of todayвЂ™s leading edge
network, telecommunications and server applications.
This 2-phase, dual output synchronous buck controller
includes strong gate drivers that support operation with
per-phase currents above 20A. The accurate 0.6V В±0.75%
reference and its integrated differential amplifier (diff
amp) allow remote sensing of the output of critical rails.
This controller has an output voltage range from 0.6V to
12.5V when used without the diff amp and from 0.6V to
3.3V with the diff amp.
The LTC3855 uses the reliable peak current mode architecture to achieve a fast and accurate current limit and real
time current sharing. Its current sense comparators are
designed to sense the inductor current with either a sense
resistor or with inductor DCR sensing. DCR sensing offers
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Статьи

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6mm × 6mm DC/DC Controller for High Current DCR Sensing Applications &mdash LT Journal
PDF, 494 Кб, Файл опубликован: 1 апр 2010
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6mm Г— 6mm DC/DC Controller for High Current
DCR Sensing Applications
Eric Gu, Theo Phillips, Mike Shriver and Kerry Holliday The LTC3855 is a versatile 2-phase synchronous buck controller IC with on-chip drivers,
remote output voltage sensing and inductor temperature sensing. These features are
ideal for high current applications where cycle-by-cycle current is measured across
the inductor (DCR sensing). Either channel is suitable for inputs up to 38V and outputs
up to 12.5V, further increasing the controllerвЂ™s versatility. The LTC3855 is based on
the popular LTC3850, described in the October 2007 issue of Linear Technology.
MONITORING THE TEMPERATURE вЂњlosslessвЂќ method is less accurate than
using a sense resistor, in large part because
as the inductor heats up, its resistance
increases with a temperature coefficient of resistivity (TCR) of 3930ppm/В°C.
Therefore as the temperature rises, the
current limit decreases. When DCR sensing When current is sensed at the inductor,
either a sense resistor is placed in series
with the inductor, or an R-C network
across the inductor is used to infer the
current information across the inductorвЂ™s DC resistance (DCR sensing). This is used, the current limit for the LTC3855
is determined by the peak sense voltage as
measured across the inductorвЂ™s DCR. The
LTC3855 includes a temperature sensing
scheme designed to compensate for the
TCR of copper by effectively raising the …

Модельный ряд

Серия: LTC3855 (8)

LTC3855EFE#PBF LTC3855EFE#TRPBF LTC3855EUJ#PBF LTC3855EUJ#TRPBF LTC3855IFE#PBF LTC3855IFE#TRPBF LTC3855IUJ#PBF LTC3855IUJ#TRPBF

Классификация производителя

Power Management > Switching Regulator > Step-Down (Buck) Regulators > Multiple Output Buck | External Power Switch Buck Controllers