LM3543M-H/NOPB_技术文档

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LM3543 Triple Port USB Power Distribution Switch and Over-Current Protection

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FEATURES

DESCRIPTION

The LM3543 is a triple high-side power switch that is

an excellent choice for use in Root, Self-Powered and

Bus-Powered USB (Universal Serial Bus) Hubs.

Independent port enables, flag signals to alert USB

controllers of error conditions, controlled start-up in

hot-plug events, and short circuit protection all satisfy

USB requirements.

2

•

Compatible with USB1.1 and USB 2.0

90mΩ (typ.) High-Side MOSFET Switch

500mA Continuous Current per Port

7 ms Fault Flag Delay Filters Hot-Plug Events

Industry Standard Pin Order

•

Short Circuit Protection with Power-Saving

Current Foldback

The LM3543 accepts input voltages between 2.7V

and 5.5V. The Enable logic inputs, available in active-

high and active-low versions, can be powered off any

voltage in the 2.7V to 5.5V range. The LM3543 limits

the continuous current through a single port to 1.25A

(max.) when it is shorted to ground.

•

Thermal Shutdown Protection

Undervoltage Lockout

Recognized by UL and Nemko

Input Voltage Range: 2.7V to 5.5V

5 µA Maximum Standby Supply Current

16-Pin SOIC Package

The low on-state resistance of the LM3543 switches

ensures the LM3543 will satisfy USB voltage drop

requirements, even when current through a switch

reaches 500 mA. Thus, High-Powered USB

Functions, Low-Powered USB Functions, and Bus-

Powered USB Hubs can all be powered off a Root or

Self-Powered USB Hub containing the LM3543.

Ambient Temperature Range: −40°C to 85°C

APPLICATIONS

•

USB Root, Self-Powered, and Bus-Powered

Hubs

Added features of the LM3543 include current

foldback to reduce power consumption in current

overload conditions, thermal shutdown to prevent

device failure caused by high-current overheating,

and undervoltage lockout to keep switches from

operating if the input voltage is below acceptable

levels.

•

USB Devices such as Monitors and Printers

General Purpose High Side Switch

Applications

1

Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of

Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.

2

All trademarks are the property of their respective owners.

PRODUCTION DATA information is current as of publication date.

Products conform to specifications per the terms of the Texas

Instruments standard warranty. Production processing does not

necessarily include testing of all parameters.

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These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam

during storage or handling to prevent electrostatic damage to the MOS gates.

Functional Diagram

Connection Diagram

Figure 1. 16-Pin SOIC

Figure 2. 16-Pin SOIC

Top View

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Typical Application Circuit

Figure 3. The LM3543 used in a Self-Powered or Root USB Hub

Absolute Maximum Ratings⁽¹⁾⁽²⁾

Voltage at IN_Xand OUT_Xpins

Voltage at EN_X(EN_X) and FLAG_Xpins

Power Dissipation⁽³⁾

−0.3V to 6V

−0.3V to 5.5V

Internally Limited

150°C

Maximum Junction Temperature

Storage Temperature Range

Lead Temperature Range (Soldering, 5 sec.)

ESD Rating⁽⁴⁾

−65°C to 150°C

260°C

2 kV

(1) Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Electrical specifications do not apply when

operating the device beyond its rated operating conditions.

(2) If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/ Distributors for availability and

specifications.

(3) The maximum allowable power dissipation is a function of the Maximum Junction Temperature (T_JMAX), Junction to Ambient Thermal

Resistance (θ_JA), and the Ambient Temperature (T_A). The LM3543 in the 16-pin SOIC package has a T_JMAXof 150°C and a θ_JAof

130°C/W. The maximum allowable power dissipation at any temperature is P_MAX= (T_JMAX− T_A)/θ_JA. Exceeding the maximum allowable

power dissipation will cause excessive die temperature, and the part will go into thermal shutdown.

(4) The Human body model is a 100 pF capacitor discharged through a 1.5 kΩ resistor into each pin.

Operating Ratings

Supply Voltage Range

2.7V to 5.5V

0 mA to 500 mA

−40°C to 125°C

Continuous Output Current Range (Each Output)

Junction Temperature Range

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DC Electrical Characteristics

Limits in standard typeface are for T_J= 25°C, and limits in boldface type apply over the full operating temperature range.

Unless otherwise specified: V_IN= 5.0V, EN_X= V_IN(LM3543-H) or EN_X= 0V (LM3543-L).

Symbol

Parameter

Conditions

V_IN= 5V, I_OUTX= 0.5A

V_IN= 3.3V, I_OUTX= 0.5A

3.0V ≤ V_IN≤ 5.5V

Min

Typ

90

Max

125

130

Units

R_ON

I_OUT

On Resistance

mΩ

95

OUT_XContinuous Output Current

OUT_XLeakage Current

0.5

A

I_LEAK-OUT

EN_X= 0 (EN_X= V_IN);

T_J= 25°C

0.01

1

µA

EN_X= 0 (EN_X= V_IN);

10

µA

− 40 ≤ T_J≤ 85°C

I_SC

OUT_XShort-Circuit Current⁽¹⁾

Overcurrent Threshold

OUT_XConnected to GND

0.8

2.0

0.1

0.2

1.25

3.2

0.3

1

A

OC_THRESH

V_{L_FLAG}

I_LEAK-FLAG

I_LEAK-EN

FLAG_XOutput-Low Voltage

FLAG_XLeakage Current

EN_xInput Leakage Current

I(FLAG_X) = 10 mA

V

2.7 ≤ V_FLAG≤ 5.5V

µA

EN_x/EN_x= 0V or

EN_x/EN_x= V_IN

−0.5

0.5

V_IH

V_IL

EN/EN Input Logic High

EN/EN Input Logic Low

2.7V ≤ V_IN≤ 5.5V

4.5V ≤ V_IN≤ 5.5V

2.7V ≤ V_IN≤ 4.5V

2.4

V

0.8

0.4

V_UVLO

Under-Voltage Lockout Threshold

Operational Supply Current

1.8

V

EN_x= V_IN(EN_x= 0 );

T_J= 25°C

375

600

800

1

µA

I_DDON

EN_x= V_IN(EN_x= 0 );

−40°C ≤ T_J≤ 125°C

µA

EN_x= 0 (EN_x= V_IN);

T_J= 25°C

I_DDOFF

Shutdown Supply Current

−40°C ≤ T_J≤ 125°C

5

(1) Thermal Shutdown will protect the device from permanent damage.

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AC Electrical Characteristics

Limits are for T_J= 25°C and V_IN= 5.0V.

Symbol

Parameter

OUT_xRise Time⁽¹⁾

OUT_xFall Time⁽²⁾

Turn-on Delay⁽³⁾

Turn-off Delay⁽⁴⁾

Flag Delay⁽⁵⁾

Conditions

C_L= 33 µF, I_LOAD= 500mA

I_FLAG= 10 mA

Min

Typ

1.5

0.9

2.9

0.7

7

Max

Units

ms

t_r

t_f

ms

t_ON

t_OFF

t_F

ms

(1) Time for OUT_xto rise from 10% to 90% of its enabled steady-state value after EN_x(EN_x) is asserted.

(2) Time for OUT_xto fall from 10% to 90% of its enabled steady-state value after EN_x(EN_x) is deasserted.

(3) Time between EN_xrising through V_IH(EN_xfalling through V_IL) and OUT_xrising through 90% of its enabled steady-state voltage.

(4) Time between EN_xfalling through V_IL(EN_xrising through V_IH) and OUT_xfalling through 10% of its enabled steady-state voltage.

(5) Time between EN_xrising through V_IN(EN_xfalling through V_IN) and FLAG_Xfalling through 0.3V when OUT_Xis connected to GND.

PIN DESCRIPTIONS

Pin Number

Pin Name

Pin Function

2, 6

IN 1, 2

Supply Inputs: These pins are the inputs to the power switches and the supply input for

the IC. In most applications they are connected together externally and to a single input

voltage supply.

1, 5

GND 1, 2

Grounds: Must be connected together and to a common ground.

Switch Outputs: These pins are the outputs of the high side switches.

Enable (Inputs): Active-high (or active-low) logic enable inputs.

15, 14, 11

3, 4, 7

OUT 1, 2, 3

LM3543-H: EN 1, 2, 3

LM3543-L: EN 1, 2, 3

16, 13, 12

8, 9, 10

FLAG 1, 2, 3

Fault Flag (Outputs): Active-low open drain outputs. Indicates over-current, UVLO or

thermal shutdown.

N/C

No Internal Connection.

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Typical Performance Characteristics

V_IN= 5.0, I_{OUT_X}= 500mA, T_A= 25°C unless otherwise specified.

R_ONvs Input Voltage

R_ONvs Junction Temperature

Figure 4.

Figure 5.

Quiescent Current, Output(s) Enabled

Quiescent Current, Output(s) Disabled

vs

Junction Temperature

Figure 6.

Figure 7.

Quiescent Current, Output(s) Enabled

Quiescent Current, Output(s) Disabled

vs

Input Voltage

Figure 8.

Figure 9.

6

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Typical Performance Characteristics (continued)

V_IN= 5.0, I_{OUT_X}= 500mA, T_A= 25°C unless otherwise specified.

Short-Circuit Output Current

Over-Current Threshold

vs

Junction Temperature

vs

Junction Temperature

Output is shorted to Ground through a 100 mΩ resistor.

Figure 10.

Figure 11.

Turn-On Delay

vs

Under-Voltage Lockout (UVLO) Threshold

vs

Input Voltage

Junction Temperature

(C_IN= 33 µF, C_OUT= 33 µF)

Figure 12.

Figure .

Turn-Off Delay

vs

Fault Flag Delay Time

vs

Junction Temperature

Input Voltage

(C_IN= 33 µF, C_OUT= 33 µF)

Figure 13.

Figure 14.

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Typical Performance Characteristics (continued)

V_IN= 5.0, I_{OUT_X}= 500mA, T_A= 25°C unless otherwise specified.

Turn-On/Turn-Off Response with 47Ω/33µF Load

Turn-On/Turn-Off Response with 10Ω/33µF Load

Figure 15.

Figure 16.

Enable Into a Short

Short Connected to Enabled Device

Output is shorted to Ground through a 100 mΩ resistor.

Figure 17.

Figure 18.

Inrush Current to Downstream Device

when LM3543 is Enabled

Over-Current Response with Ramped Load on OUT1 and

Fixed Load on OUT2

Output is shorted to Ground through a 100 mΩ resistor.

Load is two capacitors and one resistor in parallel to model an actual

USB load condition. The first capacitor has a value of 33 µF to model

the LM3543 output capacitor. The second capacitor has a value of 10

µF to model the maximum allowable input capacitance of the

downstream device. The resistor is a 47Ω resistor to model the

maximum allowable input resistance of the downstream device.

Figure 19.

Figure 20.

8

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FUNCTIONAL DESCRIPTIONS

POWER SWITCHES

The power switches that comprise the three ports of the LM3543 are N-Channel MOSFETs. They have a typical

on-state drain-to-source resistance of 90 mΩ when the input voltage is 5 V. When enabled, each switch will

supply a 500 mA minimum current to its load. In the unlikely event that a switch is enabled and the output

voltage of that switch is pulled above the input voltage, the bi-directional nature of the switch results in current to

flow from the output to the input. When a switch is disabled, current flow through the switch is prevented in both

directions.

CHARGE PUMP AND DRIVER

The gate voltages of the high-side NFET power switches are supplied by an internal charge-pump and driver

circuit combination. The charge pump is a low-current switched-capacitor circuit that efficiently generates

voltages above the LM3543 input supply. The charge pump output is used to supply a transconductance

amplifier driver circuit that controls the gate voltages of the power switches. Rise and fall times on the gates are

typically kept between 2 ms and 4 ms to limit large current surges and associated electromagnetic interference

(EMI).

ENABLE (EN_xor EN_x)

The LM3543 comes in two versions: an active-high enable version, LM3543-H, and an active-low enable version,

LM3543-L. In the LM3543-H, the EN_xpins are active-high logic inputs that, when asserted, turn on the

associated power supply switch(es). Power supply switches are controlled by the EN_xactive-low logic inputs in

the LM3543-L. With all three ports disabled on either version of the LM3543, less than 5 µA of supply current is

consumed. Both types of enable inputs, active-high and active-low, are TTL and CMOS logic compatible.

INPUT AND OUTPUT

The power supply to the control circuitry and the drains of the power-switch MOSFETs are connected to the two

input pins, IN1 and IN2. These two pins are connected externally in most standard applications. The two ground

nodes GND1 and GND2 must be connected externally in all applications.

Pins OUT1, OUT2, and OUT3 are connections to the source nodes of the power-switch MOSFETs. In a typical

application circuit, current flows through the switches from IN1 and IN2 to OUT_xtoward the load.

UNDERVOLTAGE LOCKOUT (UVLO)

Undervoltage Lockout (UVLO) prevents the MOSFET switches from turning on until the input voltage exceeds a

typical value of 1.8V.

If the input voltage drops below the UVLO threshold, the MOSFET switches are opened and fault flags are

activated. UVLO flags function only when one or more of the ports is enabled. Due to the paired nature of the

design, both FLAG1 and FLAG2 will assert if either port1 or port2 is enabled in a UVLO condition.

CURRENT LIMIT AND FOLDBACK

The current limit circuit is designed to protect the system supply, the LM3543 switches, and the load from

potential damage resulting from excessive currents. If a direct short occurs on an output of the LM3543, the input

capacitor(s) rapidly discharge through the part, activating current limit circuitry. The threshold for activating

current limiting is 2.0A (typ.). Protection is achieved by momentarily opening the MOSFET switch and then

gradually turning it on. Turn-on is halted when the current through the switch reaches the current-limit level of

1.0A (typ.) The current is held at this level until either the excessive load/short is removed or the part overheats

and thermal shutdown occurs (see THERMAL SHUTDOWN section, below). The fault flag of a switch is asserted

whenever the switch is current limiting.

If a port on the LM3543 is enabled into a short condition, the output current of that port will rise to the current-

limit level and hold there.

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When a port is in a current-limit condition, the LM3543 senses the output voltage on that port and, if it is less

than 1.0V (typ.), will reduce the output current through that port. This operation is shown in Figure 21, below. The

current reduction, or foldback, reduces power dissipation through the overloaded MOSFET switch. An additional

advantage of the foldback feature is the reduction of power required from the source supply when one or more

output ports are shorted.

Figure 21. Short-Circuit Output Current (with Foldback) vs. Output Voltage

THERMAL SHUTDOWN

The LM3543 is internally protected against excessive power dissipation by a two-stage thermal protection circuit.

If the device temperature rises to approximately 145°C, the thermal shutdown circuitry turns off any switch that is

current limited. Non-overloaded switches continue to function normally. If the die temperature rises above 160°C,

all switches are turned off and all three fault flag outputs are activated. Hysteresis ensures that a switch turned

off by thermal shutdown will not be turned on again until the die temperature is reduced to 135°C. Shorted

switches will continue to cycle off and on, due to the rising and falling die temperature, until the short is removed.

The thermal shutdown function is shown graphically in Figure 22 and Figure 23.

Figure 22. Thermal Shutdown Characteristics when only the First-Stage Thermal-Shutdown Mode is

Needed

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Figure 23. Thermal Shutdown Characteristics when Both First-Stage and Second-Stage Thermal-

Shutdown Modes are Needed

In Figure 22, port 1 is enabled into a short. When this occurs, the MOSFET switch of port 1 repeatedly opens

and closes as the device temperature rises and falls between 145°C and 135°C. In this example, the device

temperature never rises above 160°C. The second stage thermal shutdown is not used and port 2 remains

operational.

When port 1 is enabled into a short in the example illustrated in Figure 23, the device temperature immediately

rises above 160°C. A higher ambient temperature or a larger number of shorted outputs can cause the junction

temperature to increase, resulting in the difference in behavior between the current example and the previous

one. When the junction temperature reaches 160°C, all three ports are disabled (port 3 is not shown in the figure)

and all three fault-flag signals are asserted. Just prior to time index 2.5 ms, the device temperature falls below

135°C, all three ports activate, and all three fault flags are removed. The short condition remains on port 1,

however. For the remainder of the example, the device temperature cycles between 135°C and 145°C, causing

port 1 to repeatedly turn on and off but allowing the un-shorted ports to function normally.

SOFT START

When a power switch is enabled, high levels of current will flow instantaneously through the LM3543 to charge

the large capacitance at the output of the port. This is likely to exceed the over-current threshold of the device, at

which point the LM3543 will enter its current-limit mode. The amount of current used to charge the output

capacitor is then set by the current-limit circuitry. The device will exit the current-limit mode when the current

needed to continue to charge the output capacitor is less than the LM3543 current-limit level.

FAULT FLAG

The fault flags are open-drain outputs, each capable of sinking up to a 10 mA load current to typically 100 mV

above ground.

A parasitic diode exists between the flag pins and V_INpins. Pulling the flag pins to voltages higher than V_INwill

forward bias this diode and will cause an increase in supply current. This diode will also clamp the voltage on the

flag pins to a diode drop above V_IN.

The fault flag is active (pulled low) when any of the following conditions are present: under-voltage, current-limit,

or thermal-shutdown.

The LM3543 has an internal delay in reporting fault conditions that is typically 7 ms in length. In start-up, the

delay gives the device time to charge the output capacitor(s) and exit the current-limit mode before a flag signal

is set. This delay also prevents flag signal glitches from occurring when brief changes in operating conditions

momentarily place the LM3543 into one of its three error conditions. If an error condition still exists after the delay

interval has elapsed, the appropriate fault flag(s) will be asserted (pulled low) until the error condition is removed.

In most applications, the 7 ms internal flag delay eliminates the need to extend the delay with an external RC

delay network.

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Application Information

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The schematic in Figure 3 showed a typical application circuit for the LM3543. The USB specification requires

120 µF at the output of each hub. A three-port hub with 33 µF tantalum capacitors at each port output meets the

specification. These capacitors provide short-term transient current to drive downstream devices when hot-plug

events occur. Capacitors with low equivalent-series-resistance should be used to lower the inrush current flow

through the LM3543 during a hot-plug event.

The rapid change in currents seen during a hot plug event can generate electromagnetic interference (EMI). To

reduce this effect, ferrite beads in series between the outputs of the LM3543 and the downstream USB port are

recommended. Beads should also be placed between the ground node of the LM3543 and the ground nodes of

connected downstream ports. In order to keep voltage drop across the beads to a minimum, wire with small DC

resistance should be used through the ferrite beads. A 0.01 µF - 0.1 µF ceramic capacitor is recommended on

each downstream port directly between the V_busand ground pins to further reduce EMI effects.

POWER SUPPLY FILTERING

A sizable capacitor should be connected to the input of the LM3543 to ensure the voltage drop on this node is

less than 330 mV during a heavy-load hot-plug event. A 33 µF, 16V tantalum capacitor is recommended. The

input supply should be further bypassed with a 0.01 µF - 0.1 µF ceramic capacitor, placed close to the device.

The ceramic capacitor reduces ringing on the supply that can occur when a short is present at the output of a

port.

EXTENDING THE FAULT FLAG DELAY

While the 7 ms (typical) internal delay in reporting flag conditions is adequate for most applications, the delay can

be extended by connecting external RC filters to the FLAG pins, as shown in Figure 24.

Figure 24. Typical Circuit for Lengthening the Internal Flag Delay

POWER DISSIPATION AND JUNCTION TEMPERATURE

A few simple calculations will allow a designer to calculate the approximate operating temperature of the LM3543

for a given application. The large currents possible through the low resistance power MOSFET combined with

the high thermal resistance of the SOIC package, in relation to power packages, make this estimate an important

design step.

Begin the estimate by determining R_ONat the expected operating temperature using the graphs in the Typical

Performance Characteristics section of this datasheet. Next, calculate the power dissipation through the switch

with Equation 1.

2

PD = R_ON* I_DS

(1)

Note: Equation for power dissipation neglects portion that comes from LM3543 quiescent current because this

value will almost always be insignificant.

Using this figure, determine the junction temperature with Equation 2.

T_J= PD * θ_JA+ T_A.

where

•

θ_JA= SOIC Thermal Resistance: 130°C/W and T_A= Ambient Temperature (°C).

(2)

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Compare the calculated temperature with the expected temperature used to estimate R_ON. If they do not

reasonably match, re-estimate R_ONusing a more appropriate operating temperature and repeat the calculations.

Reiterate as necessary.

PCB LAYOUT CONSIDERATIONS

In order to meet the USB requirements for voltage drop, droop and EMI, each component used in this circuit

must be evaluated for its contribution to the circuit performance. These principles are illustrated in Figure 25. The

following PCB layout rules and guidelines are recommended

1. Place the switch as close to the USB connector as possible. Keep all V_bustraces as short as possible and

use at least 50-mil, 1 ounce copper for all V_bustraces. Solder plating the traces will reduce the trace

resistance.

2. Avoid vias as much as possible. If vias are used, use multiple vias in parallel and/or make them as large as

possible.

3. Place the output capacitor and ferrite beads as close to the USB connector as possible.

4. If ferrite beads are used, use wires with minimum resistance and large solder pads to minimize connection

resistance.

Figure 25. Self-Powered Hub Connections and Per-Port Voltage Drop

Typical Applications

ROOT AND SELF-POWERED USB HUBS

The LM3543 has been designed primarily for use in root and self-powered USB hubs. In this application, the

switches of the LM3543 are used to connect the power source of the hub to the power bus used by downstream

devices and to protect the hub from dangerously excessive loads and shorts to ground. A high-power bus-

powered function, low-power bus-powered function, or a bus-powered hub can be driven through a single port of

the LM3543. A schematic of a circuit that uses the LM3543 for power-supply switching in a typical root or self-

powered hub was shown earlier in this datasheet in Figure 3.

Voltage drop requirements of USB power supplies require the power outputs of the root and self-powered hubs

to be no less than 4.75V. For this reason, it is recommended that a 5V power supply with a ±3% output voltage

tolerance is used in this application. Combining a 3% supply with a low-resistance PCB design and the low on-

resistance of the LM3543 power switches will ensure that the hub power outputs meet the USB voltage drop

specification even with a 500mA load, the maximum allowed in the USB standard.

BUS-POWERED USB HUBS

The LM3543 is capable of performing the power supply switching functions required in Bus-Powered hubs. Use

here is very similar to the configuration used in root and self-powered hubs. With bus-powered hubs, however,

there is no internal power supply to drive the input pins of the LM3543. Instead, the input pins should be

connected to the power bus supplied by the upstream hub.

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USB BUS-POWERED FUNCTIONS AND GENERAL IN-RUSH CURRENT LIMITING APPLICATIONS

The LM3543 can be placed at the power-supply input of USB bus-powered functions, or other similar devices, to

protect them from high in-rush currents. If the current being delivered to the device were to exceed the 2.0A

over-current threshold (typ.) of the LM3543, switches in violation would open to protect the device from damage.

In addition to in-rush current limiting, the LM3543 can be used in high-power bus-powered functions to keep

current levels of the function in compliance during power-up. The USB specification requires the staged switching

of power when connecting high-power functions to the bus. When a high-power function is initially connected to

the bus, it must not draw more than one unit supply (100mA). After a connection is detected and enumerated,

and if the upstream device is capable of supplying the required power, the high-power function may draw up to

five unit loads (500mA). With the proper control signals, the LM3543 can be used to achieve this staged power

connection. When the function is connected to the bus, one or more of the LM3543 switches can be closed to

connect bus power only to circuitry needed during the connection and enumeration process. If the function is to

be powered fully, remaining switches on the LM3543 can be closed to connect all blocks of the function to the

power bus. Figure 26 illustrates how the LM3543 can be connected for use in bus powered functions.

LM3543-H

Internal Function

(with start-up

circuitry)

15

14

11

2

6

OUT1

OUT2

OUT3

IN1

IN2

V

BUS

10 mF

0.1 mF

10 mF

0.1 mF

D+

D-

GND

3.3V Power

Supply

Internal

Function

Internal

Function

16

13

12

FLAG1

FLAG2

FLAG3

USB

Control

8, 9, 10

3

4

7

NC

EN1

EN2

EN3

1

5

GND1

GND2

Figure 26. Using the LM3543 in USB Bus-Powered Functions

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REVISION HISTORY

Changes from Revision D (March 2013) to Revision E

Page

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型号：	LM3543M-H/NOPB
厂家：	TEXAS INSTRUMENTS
描述：	IC,POWER SUPPLY SWITCHING CIRCUIT,CMOS,SOP,16PIN,PLASTIC 开关光电二极管
文件：	总16页 (文件大小：528K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

LM3543M-H/NOPB [TI]

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LM3543MX-H/NOPB

LM3543MX-L

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LM3544M-L/NOPB