LMZM33606 3.5V 至 36V 输入、1V 至 20V 输出、6A 电源模块

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1 特性

较小的总体解决方案尺寸：< 250mm²
- 所需的外部组件数低至 4 个
- 16mm × 10mm × 4mm QFN 封装
支持 5V、12V、24V、28V 输入电源轨
- 1V 至 20V 输出电压范围
- 引脚与 4A LMZM33604 兼容
符合 EN55011 辐射发射标准
可配置为负输出电压
用于实现设计灵活性的可调节功能
- 开关频率（350kHz 至 2.2MHz）
- 可与外部时钟保持同步
- 可选自动模式或 FPWM 模式
  - 自动：提升轻负载下的效率
  - FPWM：在整个负载上具有固定频率
- 可调软启动和跟踪输入
- 精密使能功能，用于对系统 UVLO 进行编程
保护特性
- 断续模式电流限制
- 过热保护
- 电源正常输出
可在恶劣环境中运行
- 在 85°C 且无气流的情况下具有高达 50W 的输出功率
- 工作结温范围：–40°C 至 +125°C
- 工作环境温度范围：–40°C 至 +105°C
- 通过了 Mil-STD-883D 冲击和振动测试

2 应用

工业、医疗和测试设备
通用宽输入电压稳压
反相输出应用

简化电路原理图

3 说明

LMZM33606 电源模块是一款易于使用的集成式电源解决方案，它在一个低厚度的封装内整合了一个带有功率 MOSFET 的 6A 直流/直流转换器、一个屏蔽式电感器和多个无源器件。此电源解决方案仅需四个外部组件，并且省去了设计流程中的环路补偿和电感器元件选择过程。

该器件采用 16mm × 10mm × 4mm、41 引脚 QFN 封装，可轻松焊接到印刷电路板上，并可实现紧凑的低厚度负载点设计。LMZM33606 的全套功能包括电源正常指示、可调节软启动、跟踪、同步、可编程 UVLO、预偏置启动、可选自动或 FPWM 模式以及过流和过热保护。可针对反相应用将 LMZM33606 配置为负输出电压。

器件信息

器件型号	封装	封装尺寸（标称值）
LMZM33606	QFN (41)	16.00mm × 10.00mm

空白

最小解决方案尺寸

空白

典型效率（自动模式）

4 修订历史记录

Changes from A Revision (October 2018) to B Revision

Added information on internal LDO and BIAS_SELGo

Changes from * Revision (June 2018) to A Revision

首次发布生产数据数据表Go

5 Pin Configuration and Functions

RLX Package

41-Pin QFN

Top View

Pin Functions

PIN		TYPE	DESCRIPTION
NAME	NO.	TYPE	DESCRIPTION
AGND	16, 21	G	Analog ground. Zero voltage reference for internal references and logic. These pins are not connected to one another internal to the device and must be connected to one another externally. Do not connect these pins to PGND; the AGND to PGND connection is made internal to the device. See the Layout section of the datasheet for a recommended layout.
BIAS_SEL	10	I	Optional BIAS LDO supply input. An internal 470 nF capacitor is placed between this pin and PGND. Do not float; tie to PGND if not used. Tie to VOUT if 3.3 V ≤ VOUT ≤ 18 V, or tie to an external 3.3-V or 5-V rail if available to improve efficiency.
DNC	7	—	Do not connect. This pin is connected to internal circuitry. Do not connect this pin to AGND, PGND, or any other voltage. This pin must be soldered to an isolated pad..
EN	20	I	Precision enable input to regulator. Do not float. High = ON, Low = OFF. Can be tied to VIN. Precision enable input allows adjustable system UVLO using external resistor divider.
FB	15	I	Feedback input. Connect the center point of the feedback resistor divider to this pin. Connect the upper resistor (R_FBT) of the feedback divider to V_OUT at the desired point of regulation. Connect the lower resistor (R_FBB) of the feedback divider to AGND.
NC	14	—	Not internally connected.
PGND	8, 11, 23, 30, 34, 35, 38, 40, 41	G	Power ground. This is the return current path for the power stage of the device. Connect these pins to the low side of the input source, load, and bypass capacitors associated with VIN and VOUT using power ground planes on the PCB. Not all pins are connected to PGND internal to the device; connections must be made externally. Connect pad 40 and 41 to the ground planes using multiple vias for good thermal performance.
PGOOD	17	O	Open drain output for power-good flag. Internal to the device, a 100-kΩ pullup resistor is placed between this pin and the PGOOD_PU pin.
PGOOD_PU	18	I	Power-good pull-up supply. Connect to logic rail or other DC voltage no higher than 20 V.
RT	12	I	An external timing resistor connected between this pin and AGND adjusts the switching frequency of the device. If floating, the default switching frequency is 500 kHz. Do not short to ground.
SS/TRK	13	I	Soft start / tracking control pin. Leave this pin floating to use the 5-ms internal soft-start ramp.To increase the internal soft start ramp time, simply connect a capacitor between this pin and AGND. This pin sources 2-μA of current to charge this external capacitor. Connect to external voltage ramp for tracking. Do not connect to ground.
SW	1, 2, 3, 4, 5, 6, 31, 32, 33	O	Switch node. Connect these pins to a small copper island under the device for thermal relief. Do not place any external components on these pins or tie them to a pin of another function.
SYNC/MODE	19	I	Synchronization input and Mode setting pin. Do not float; tie to AGND or logic high if not used. Connect to an external clock to synchronize (see Synchronization (SYNC/MODE)). Connect to AGND to select Auto mode or connect to logic high to select FPWM mode. (see Mode Select (Auto or FPWM)).
VCC	9	O	Output of internal bias supply. Used to supply internal control circuits and drivers. Do not place any external component on this pin or tie it to a pin of another function.
VIN	22, 39	I	Input supply voltage. Connect external input capacitors between these pins and PGND.
VOUT	24, 25, 26, 27, 28, 29, 36, 37	O	Output voltage. These pins are connected to the output of the internal inductor. Connect these pins to the output VOUT load and connect external bypass capacitors between these pins and PGND.

6 Specifications

6.1 Absolute Maximum Ratings

Over operating ambient temperature range (unless otherwise noted)⁽¹⁾

		MIN	MAX	UNIT
Input voltage	VIN to PGND	-0.3	42	V
	EN to AGND	-0.3	V_IN + 0.3	V
	FB, RT, SS/TRK to AGND	-0.3	5	V
	PGOOD to AGND	-0.1	20	V
	SYNC/MODE to AGND	-0.3	5.5	V
	BIAS_SEL to AGND	-0.3	Lower of (V_IN+0.3) and 20	V
	AGND to PGND	-0.3	0.3	V
Output voltage	VOUT to PGND	-0.3	V_IN	V
	SW to PGND	-0.3	V_IN + 0.3	V
	SW to PGND (<10 ns transients)	-3.5	42	V
	VCC to PGND	-0.3	5	V
Peak Reflow Case Temperature			240	°C
Maximum Number of Reflows Allowed			1
Temperature	Maximum junction temperature, T_J⁽²⁾	-40	125	°C
Temperature	Storage temperature, T_stg	-55	150	°C
Mechanical shock	Mil-STD-883D, Method 2002.3, 1 msec, 1/2 sine, mounted		500	G
Mechanical vibration	Mil-STD-883D, Method 2007.2, 20 to 2000 Hz		20	G

(1) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under the recommended operating conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.

(2) The ambient temperature is the air temperature of the surrounding environment. The junction temperature is the temperature of the internal power IC when the device is powered. Operating below the maximum ambient temperature, as shown in the safe operating area (SOA) curves in the typical characteristics sections, ensures that the maximum junction temperature of any component inside the module is never exceeded.

6.2 ESD Ratings

			VALUE	UNIT
V_(ESD)	Electrostatic discharge	Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001⁽¹⁾	±1500	V
V_(ESD)	Electrostatic discharge	Charged-device model (CDM), per JEDEC specification JESD22-C101⁽²⁾	±1000	V

(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.

(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.

6.3 Recommended Operating Conditions

Over operating ambient temperature range (unless otherwise noted)

	MIN	MAX	UNIT
Input voltage, V_IN	3.5⁽¹⁾	36	V
Output voltage, V_OUT	1	20	V
EN voltage, V_EN	0	VIN	V
PGOOD pullup voltage, V_PGOOD	0	18	V
PGOOD sink current	0	5	mA
BIAS_SEL	3.3	Lower of VIN and 18	V
Output current, I_OUT	0	6	A
Switching frequency, F_SW	350	1200	kHz
Operating ambient temperature, T_A	–40	105	°C
Input Capacitance, C_IN	20⁽²⁾		µF
Output Capacitance, C_OUT	min⁽³⁾	700	µF

(1) For output voltages ≤ 5 V, the recommended minimum V_IN is 3.5 V or (VOUT + 1 V), whichever is greater. For output voltages > 5 V, the recommended minimum V_IN is (1.1 × VOUT). See Voltage Dropout for more information.

(2) A minimum of 20 µF ceramic input capacitance is required for proper operation. An additional 100 µF of bulk capacitance is recommended for applications with transient load requirements. (see Input Capacitor Selection).

(3) The minimum amount of required output capacitance varies depending on the output voltage (see Output Capacitor Selection).