FDD6637F085 - FAIRCHILD SEMICONDUCTOR

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October 2015

FAN53601 / FAN53611 • Rev. 1.8

FAN53601 / FAN53611 — 6 MHz 600 mA / 1 A Synchronous Buck Regulator

FAN53601 / FAN53611

6 MHz, 600 mA / 1 A Synchronous Buck Regulator

Features

 600 mA or 1 A Output Current Capability

 24 µA Typical Quiescent Current

 6 MHz Fixed-Frequency Operation

 Best-in-Class Load Transient Response

 Best-in-Class Efficiency

 2.3 V to 5.5 V Input Voltage Range

 Low Ripple Light-Load PFM Mode

 Forced PWM and External Clock Synchronization

 Internal Soft-Start

 Input Under-Voltage Lockout (UVLO)

 Thermal Shutdown and Overload Protection

 Optional Output Discharge

 6-Bump WLCSP, 0.4 mm Pitch

Applications

 3G, 4G, WiFi®, WiMAX™, and WiBro® Data Cards

 Tablets

 DSC, DVC

 Netbooks®, Ultra-Mobile PCs

All trademarks are the property of their respective owners.

Description

The FAN53601/11 is a 6 MHz, step-down switching voltage

regulator, available in 600 mA or 1 A options, that delivers a

fixed output from an input voltage supply of 2.3 V to 5.5 V.

Using a proprietary architecture with synchronous

rectification, the FAN53601/11 is capable of delivering a

peak efficiency of 92%, while maintaining efficiency over

80% at load currents as low as 1 mA.

The regulator operates at a nominal fixed frequency of

6 MHz, which reduces the value of the external components

to as low as 470 nH for the output inductor and 4.7 µF for the

output capacitor. In addition, the Pulse Width Modulation

(PWM) modulator can be synchronized to an external

frequency source.

At moderate and light loads, Pulse Frequency Modulation

(PFM) is used to operate the device in Power-Save Mode

with a typical quiescent current of 24 µA. Even with such a

low quiescent current, the part exhibits excellent transient

response during large load swings. At higher loads, the

system automatically switches to fixed-frequency control,

operating at 6 MHz. In Shutdown Mode, the supply current

drops below 1 µA, reducing power consumption. For

applications that require minimum ripple or fixed frequency,

PFM Mode can be disabled using the MODE pin.

The FAN53601/11 is available in 6-bump, 0.4 mm pitch,

Wafer-Level Chip-Scale Package (WLCSP).

Figure 1. Typical Application

MODE

GND

L1 CIN

2.2F

470nH

4.7FCOUT

VIN

FAN53601 / FAN53611 • Rev. 1.8 2

FAN53601 / FAN53611 — 6 MHz 600 mA / 1 A Synchronous Buck Regulator

Ordering Information

Part Number

Output

Voltage(1)

Max. Output

Current

Active

Discharge(2)

Max.

VIN

Package

Temperature

Range

Packing

FAN53601AUC10X

1.000 V

600 mA

Yes

5.5 V

WLCSP-6,

0.4 mm Pitch

-40 to +85°C

Tape and

Reel

FAN53601AUC105X

1.050 V

600 mA

Yes

FAN53611AUC11X

1.100 V

1 A

Yes

FAN53611AUC115X

1.150 V

1 A

Yes

FAN53611AUC13X

1.300 V

1 A

Yes

FAN53611AUC135X

1.350 V

1 A

Yes

FAN53611UC123X

1.233 V

1 A

FAN53601UC182X

1.820 V

600 mA

FAN53611AUC205X

2.050 V

1 A

Yes

FAN53611AUC123X

1.233 V

1 A

Yes

FAN53611AUC12X

1.200 V

1 A

Yes

FAN53611AUC18X

1.800 V

1 A

Yes

Notes:

1. Other voltage options available on request. Contact a Fairchild representative.

2. All voltage and output current options are available with or without active discharge. Contact a Fairchild representative.

Pin Configurations

MODE

VIN

GND

A2 MODE

VIN

GND

Figure 2. Bumps Facing Down

Figure 3. Bumps Facing Up

Pin Definitions

Pin #

Name

Description

MODE

MODE. Logic 1 on this pin forces the IC to stay in PWM Mode. A logic 0 allows the IC to

automatically switch to PFM during light loads. The regulator also synchronizes its switching

frequency to four times the frequency provided on this pin. Do not leave this pin floating.

Switching Node. Connect to output inductor.

Feedback / VOUT. Connect to output voltage.

GND

Ground. Power and IC ground. All signals are referenced to this pin.

Enable. The device is in Shutdown Mode when voltage to this pin is < 0.4 V and enabled when

> 1.2 V. Do not leave this pin floating.

VIN

Input Voltage. Connect to input power source.

FAN53601 / FAN53611 • Rev. 1.8 3

FAN53601 / FAN53611 — 6 MHz 600 mA / 1 A Synchronous Buck Regulator

Absolute Maximum Ratings

Stresses exceeding the absolute maximum ratings may damage the device. The device may not function or be operable above

the recommended operating conditions and stressing the parts to these levels is not recommended. In addition, extended

exposure to stresses above the recommended operating conditions may affect device reliability. The absolute maximum ratings

are stress ratings only.

Symbol

Parameter

Min.

Max.

Units

VIN

Input Voltage

-0.3

7.0

VSW

Voltage on SW Pin

-0.3

VIN + 0.3(3)

VCTRL

EN and MODE Pin Voltage

-0.3

VIN + 0.3(3)

Other Pins

-0.3

VIN + 0.3(3)

ESD

Electrostatic Discharge

Protection Level

Human Body Model per JESD22-A114

2.0

Charged Device Model per JESD22-C101

1.5

Junction Temperature

-40

+150

°C

TSTG

Storage Temperature

-65

+150

°C

Lead Soldering Temperature, 10 Seconds

+260

°C

Note:

3. Lesser of 7 V or VIN+0.3 V.

Recommended Operating Conditions

The Recommended Operating Conditions table defines the conditions for actual device operation. Recommended operating

conditions are specified to ensure optimal performance to the datasheet specifications. Fairchild does not recommend exceeding

them or designing to Absolute Maximum Ratings.

Symbol

Parameter

Min.

Typ.

Max.

Units

VCC

Supply Voltage Range

2.3

5.5

IOUT

Output Current for FAN53601

600

Output Current for FAN53611

Inductor

470

CIN

Input Capacitor

2.2

µF

COUT

Output Capacitor

1.6

4.7

12.0

µF

Operating Ambient Temperature

-40

+85

°C

Operating Junction Temperature

-40

+125

°C

Thermal Properties

Junction-to-ambient thermal resistance is a function of application and board layout. This data is measured with four-layer 2s2p

boards in accordance to JEDEC standard JESD51. Special attention must be paid to not exceed junction temperature TJ(max) at a

given ambient temperature TA.

Symbol

Parameter

Typical

Unit

JA

Junction-to-Ambient Thermal Resistance

125

°C/W

FAN53601 / FAN53611 • Rev. 1.8 4

FAN53601 / FAN53611 — 6 MHz 600 mA / 1 A Synchronous Buck Regulator

Electrical Characteristics

Minimum and maximum values are at VIN = VEN = 2.3 V to 5.5 V, VMODE = 0 V (AUTO Mode), TA = -40°C to +85°C; circuit of

Figure 1 , unless otherwise noted. Typical values are at TA = 25°C, VIN = VEN = 3.6 V.

Symbol

Parameter

Conditions

Min.

Typ.

Max.

Units

Power Supplies

Quiescent Current

No Load, Not Switching

µA

PWM Mode

I(SD)

Shutdown Supply Current

EN = GND, VIN = 3.6 V

0.25

1.00

µA

VUVLO

Under-Voltage Lockout Threshold

Rising VIN

2.15

2.27

V

VUVHYST

Under-Voltage Lockout Hysteresis

200

Logic Inputs: EN and MODE Pins

VIH

Enable HIGH-Level Input Voltage

1.2

VIL

Enable LOW-Level Input Voltage

0.4

VLHYST

Logic Input Hysteresis Voltage

100

IIN

Enable Input Leakage Current

Pin to VIN or GND

0.01

1.00

µA

Switching and Synchronization

fSW

Switching Frequency(4)

VIN = 3.6 V, TA = 25°C, PWM

Mode, ILOAD = 10 mA

5.4

6.0

6.6

MHz

fSYNC

MODE Synchronization Range(4)

Square Wave at MODE Input

1.3

1.5

1.7

MHz

Regulation

Output Voltage

Accuracy

1.000 V

ILOAD = 0 to 600 mA

0.953

1.000

1.048

PWM Mode

0.967

1.000

1.034

1.35 V

ILOAD = 0 to 1 A

1.298

1.350

1.402

PWM mode

1.309

1.350

1.391

1.233 V

ILOAD = 0 to 1 A

1.185

1.233

1.281

PWM Mode

1.192

1.233

1.274

1.820 V

ILOAD = 0 to 600 mA

1.755

1.820

1.885

PWM Mode

1.781

1.820

1.859

1.100 V

ILOAD = 0 to 1 A

1.054

1.100

1.147

PWM Mode

1.061

1.100

1.140

1.300 V

ILOAD = 0 to 1 A

1.250

1.300

1.350

PWM Mode

1.259

1.300

1.341

1.150 V

ILOAD = 0 to 1 A

1.104

1.150

1.196

PWM Mode

1.110

1.150

1.190

1.050 V

ILOAD = 0 to 600 mA

1.003

1.050

1.097

PWM Mode

1.016

1.050

1.084

2.050 V

ILOAD = 0 to 1 A, VIN = 2.7 V to

5.5 V

1.973

2.050

2.127

PWM Mode, VIN = 2.7 V to 5.5 V

2.004

2.050

2.096

1.200 V

ILOAD = 0 to 1 A

1.152

1.200

1.248

PWM Mode

1.160

1.200

1.240

1.800 V

ILOAD = 0 to 1 A

1.732

1.800

1.868

PWM Mode

1.756

1.800

1.844

tSS

Soft-Start

VIN = 4.5 V, From EN Rising Edge

180

300

µs

FAN53601 / FAN53611 • Rev. 1.8 5

FAN53601 / FAN53611 — 6 MHz 600 mA / 1 A Synchronous Buck Regulator

Electrical Characteristics (Continued)

Minimum and maximum values are at VIN = VEN = 2.3 V to 5.5 V, VMODE = 0 V (AUTO Mode), TA = -40°C to +85°C; circuit of

Figure 1 , unless otherwise noted. Typical values are at TA = 25°C, VIN = VEN = 3.6 V.

Symbol

Parameter

Conditions

Min.

Typ.

Max.

Units

Output Driver

RDS(on)

PMOS On Resistance

VIN = VGS = 3.6 V

175

m

NMOS On Resistance

VIN = VGS = 3.6 V

165

m

ILIM(OL)

PMOS Peak Current Limit

Open-Loop for FAN53601,

VIN = 3.6 V, TA = 25°C

900

1100

1250

Open-Loop for FAN53611,

VIN = 3.6 V, TA = 25°C

1500

1750

2000

RDIS

Output Discharge Resistance

EN = GND

230



TTSD

Thermal Shutdown

150

°C

THYS

Thermal Shutdown Hysteresis

°C

Notes:

4. Limited by the effect of tOFF minimum (see Operation Description section).

5. The Electrical Characteristics table reflects open-loop data. Refer to the Operation Description and Typical Characteristics Sections for

closed-loop data.

FAN53601 / FAN53611 • Rev. 1.8 6

FAN53601 / FAN53611 — 6 MHz 600 mA / 1 A Synchronous Buck Regulator

Typical Performance Characteristics

Unless otherwise noted, V IN = VEN = 3.6 V, VMODE = 0 V (AUTO Mode), VOUT = 1.82 V, and TA = 25°C.

70%

75%

80%

85%

90%

95%

0200 400 600 800 1000

Efficiency

Load Current (mA)

2.7 VIN

3.6 VIN

4.2 VIN

5.0 VIN

60%

62%

64%

66%

68%

70%

72%

74%

76%

78%

80%

82%

84%

86%

88%

90%

92%

0200 400 600 800 1000

Efficiency

Load Current (mA)

- 40C, AUTO

+25C, AUTO

+85C, AUTO

- 40C, PWM

+25C, PWM

+85C, PWM

Figure 4. Efficiency vs. Load Current and

Input Voltage, Auto Mode, Dotted for Decreasing Load

Figure 5. Efficiency vs. Load Current

and Temperature, Auto Mode, Dotted for FPWM

64%

66%

68%

70%

72%

74%

76%

78%

80%

82%

84%

86%

88%

90%

0200 400 600 800 1000

Efficiency

Load Current (mA)

2.7 VIN

3.6 VIN

4.2 VIN

5.0 VIN

60%

62%

64%

66%

68%

70%

72%

74%

76%

78%

80%

82%

84%

86%

88%

90%

0200 400 600 800 1000

Efficiency

Load Current (mA)

- 40C, AUTO

+25C, AUTO

+85C, AUTO

- 40C, PWM

+25C, PWM

+85C, PWM

Figure 6. Efficiency vs. Load Current and

Input Voltage, V

OUT

= 1.23 V, Auto Mode, Dotted

for Decreasing Load

Figure 7. Efficiency vs. Load Current

and Temperature, V

OUT

= 1.23 V, Auto Mode,

Dotted for FPWM

-2

-1

0100 200 300 400 500 600

Output Regulation (%)

Load Current (mA)

2.7VIN, AUTO

3.6VIN, AUTO

4.2VIN, AUTO

5.0VIN, AUTO

2.7VIN, PWM

3.6VIN, PWM

4.2VIN, PWM

5.0VIN, PWM

64%

66%

68%

70%

72%

74%

76%

78%

80%

82%

84%

86%

88%

90%

0100 200 300 400 500 600

Efficiency

Load Current (mA)

2.7 VIN

3.6 VIN

4.2 VIN

5.0 VIN

Figure 8. Output Regulation vs. Load Current,

OUT

= 1.00 V, Dotted for Auto Mode

Figure 9. Efficiency vs. Load Current, V

OUT

= 1.00 V,

Dotted for Decreasing Load

FAN53601 / FAN53611 • Rev. 1.8 7

FAN53601 / FAN53611 — 6 MHz 600 mA / 1 A Synchronous Buck Regulator

Typical Performance Characteristics (Continued)

Unless otherwise noted, VIN = VEN = 3.6 V, VMODE = 0 V (AUTO Mode), VOUT = 1.82 V, and TA = 25°C.

-2

-1

0200 400 600 800 1000

Output Regulation (%)

Load Current (mA)

2.7VIN, AUTO

3.6VIN, AUTO

4.2VIN, AUTO

5.0VIN, AUTO

2.7VIN, PWM

3.6VIN, PWM

4.2VIN, PWM

5.0VIN, PWM

-2

-1

0200 400 600 800 1000

Output Regulation (%)

Load Current (mA)

2.7VIN, AUTO

3.6VIN, AUTO

4.2VIN, AUTO

5.0VIN, AUTO

2.7VIN, PWM

3.6VIN, PWM

4.2VIN, PWM

5.0VIN, PWM

Figure 10. ∆V

OUT

(%) vs. Load Current and Input

Voltage, Normalized to 3.6 V

, 500 mA Load, FPWM,

Dotted for Auto Mode

Figure 11. ∆V

OUT

(%) vs. Load Current and Input

Voltage, V

OUT

= 1.23 V, Normalized to 3.6 V

, 500 mA

Load, FPWM, Dotted for Auto Mode

100

150

200

250

300

350

2.5 3.0 3.5 4.0 4.5 5.0 5.5

Load Current (mA)

Input Voltage (V)

PWM

PFM

100

150

200

250

300

350

2.5 3.0 3.5 4.0 4.5 5.0 5.5

Load Current (mA)

Input Voltage (V)

PWM

PFM

Figure 12. PFM / PWM Boundary vs. Input Voltage

Figure 13. PFM / PWM Boundary vs. Input Voltage,

OUT

= 1.23 V

2.5 3.0 3.5 4.0 4.5 5.0 5.5

Input Current (A)

Input Voltage (V)

- 40C, EN=VIN

+25C, EN=VIN

+85C, EN=VIN

- 40C, EN=1.8V

+25C, EN=1.8V

+85C, EN=1.8V

2.5 3.0 3.5 4.0 4.5 5.0 5.5

Input Current (mA)

Input Voltage (V)

-40C

+25C

+85C

Figure 14. Quiescent Current vs. Input Voltage and

Temperature, Auto Mode; EN = V

Solid, Dotted for

EN=1.8 V (-40

C, +25

C, +85

Figure 15. Quiescent Current vs. Input Voltage and

Temperature, Mode = EN = V

(FPWM)

FAN53601 / FAN53611 • Rev. 1.8 8

FAN53601 / FAN53611 — 6 MHz 600 mA / 1 A Synchronous Buck Regulator

Typical Performance Characteristics (Continued)

Unless otherwise noted, V IN = VEN = 3.6 V, VMODE = 0 V (AUTO Mode), VOUT = 1.82 V, and TA = 25°C.

0200 400 600 800 1000

Output Ripple (mVpp)

Load Current (mA)

2.7VIN, AUTO

3.6VIN, AUTO

5.0VIN, AUTO

2.7VIN, PWM

3.6VIN, PWM

5.0VIN, PWM

1,500

3,000

4,500

6,000

7,500

0200 400 600 800 1000

Switching Frequency (KHz)

Load Current (mA)

2.7VIN, AUTO

3.6VIN, AUTO

5.0VIN, AUTO

2.7VIN, PWM

3.6VIN, PWM

5.0VIN, PWM

Figure 16. Output Ripple vs. Load Current and

Input Voltage, FPWM, Dotted for Auto Mode

Figure 17. Frequency vs. Load Current and

Input Voltage, Auto Mode, Dotted for FPWM

Figure 18. Load Transient, 10-200-10 mA, 100 ns Edge

Figure 19. Load Transient, 200-800-200 mA,

100 ns Edge

Figure 20. Line Transient, 3.3-3.9-3.3 V

, 10 µs Edge,

36 mA Load

Figure 21. Line Transient, 3.3-3.9-3.3 V

, 10 µs Edge,

600 mA Load

FAN53601 / FAN53611 • Rev. 1.8 9

FAN53601 / FAN53611 — 6 MHz 600 mA / 1 A Synchronous Buck Regulator

Typical Performance Characteristics (Continued)

Unless otherwise noted, V IN = VEN = 3.6 V, VMODE = 0 V (AUTO Mode), VOUT = 1.82 V, and TA = 25°C.

Figure 22. Combined Line / Load Transient, 3.9-3.3 V

10 µs Edge, 36-400 mA Load, 100 ns Edge

Figure 23. Combined Line / Load Transient, 3.3-3.9 V

10 µs Edge, 400-36 mA Load, 100 ns Edge

Figure 24. Startup, 50 Ω Load

Figure 25. Startup, 3 Ω Load

Figure 26. Shutdown, 10k Ω Load, No Output Discharge

Figure 27. Shutdown, No Load, Output Discharge

Enabled

FAN53601 / FAN53611 • Rev. 1.8 10

FAN53601 / FAN53611 — 6 MHz 600 mA / 1 A Synchronous Buck Regulator

Typical Performance Characteristics (Continued)

Unless otherwise noted, V IN = VEN = 3.6 V, VMODE = 0 V (AUTO Mode), VOUT = 1.82 V, and TA = 25°C.

Figure 28. Over-Current, Load Increasing Past

Current Limit, FAN53601

Figure 29. 250 mΩ Fault, Rapid Fault,

Hiccup, FAN53601

Figure 30. Over-Current, Load Increasing Past

Current Limit, FAN53611

Figure 31. 250 mΩ Fault, Rapid Fault,

Hiccup, FAN53611

0.1 1 10 100 1000

PSRR (dB)

Frequency (KHz)

36mA Load

600mA Load

0.1 1 10 100 1000

PSRR (dB)

Frequency (KHz)

24mA Load

500mA Load

Figure 32. PSRR, 50 Ω and 3 Ω Load

Figure 33. PSRR, 50 Ω and 3 Ω Load, V

OUT

= 1.23 V

FAN53601 / FAN53611 • Rev. 1.8 11

FAN53601 / FAN53611 — 6 MHz 600 mA / 1 A Synchronous Buck Regulator

Operation Description

The FAN53601/11 is a 6 MHz, step-down switching voltage

regulator available in 600 mA or 1 A options that delivers a

fixed output from an input voltage supply of 2.3 V to 5.5 V.

Using a proprietary architecture with synchronous

rectification, the FAN53601/11 is capable of delivering a

peak efficiency of 92%, while maintaining efficiency over

80% at load currents as low as 1 mA.

The regulator operates at a nominal fixed frequency of

6 MHz, which reduces the value of the external components

to as low as 470 nH for the output inductor and 4.7 µF for the

output capacitor. In addition, the PWM modulator can be

synchronized to an external frequency source.

Control Scheme

The FAN53601/11 uses a proprietary, non-linear, fixed-

frequency PWM modulator to deliver a fast load transient

response, while maintaining a constant switching frequency

over a wide range of operating conditions. The regulator

performance is independent of the output capacitor ESR,

allowing for the use of ceramic output capacitors. Although

this type of operation normally results in a switching frequency

that varies with input voltage and load current, an internal

frequency loop holds the switching frequency constant over a

large range of input voltages and load currents.

For very light loads, the FAN53601/11 operates in

Discontinuous Current Mode (DCM) single-pulse PFM Mode,

which produces low output ripple compared with other PFM

architectures. Transition between PWM and PFM is

seamless, allowing for a smooth transition between DCM

and CCM.

Combined with exceptional transient response

characteristics, the very low quiescent current of the

controller maintains high efficiency; even at very light loads;

while preserving fast transient response for applications

requiring tight output regulation.

Enable and Soft-Start

When EN is LOW, all circuits are off and the IC draws

~250 nA of current. When EN is HIGH and VIN is above its

UVLO threshold, the regulator begins a soft-start cycle. The

output ramp during soft-start is a fixed slew rate of 50 mV/s

from Vout = 0 to 1 V, then 12.5 mV/µs until the output reaches

its setpoint. Regardless of the state of the MODE pin, PFM

Mode is enabled to prevent current from being discharged

from COUT if soft-start begins when COUT is charged.

In addition, all voltage options can be ordered with a feature

that actively discharges FB to ground through a 230  path

when EN is LOW. Raising EN above its threshold voltage

activates the part and starts the soft-start cycle. During soft-

start, the internal reference is ramped using an exponential

RC shape to prevent overshoot of the output voltage. Current

limiting minimizes inrush during soft-start.

The current-limit fault response protects the IC in the event

of an over-current condition present during soft-start. As a

result, the IC may fail to start if heavy load is applied during

startup and/or if excessive COUT is used.

The current required to charge COUT during soft-start

commonly referred to as “displacement current” is given as:

CI OUTDISP 

(1)

where

refers to the soft-start slew rate.

To prevent shut down during soft-start, the following condition

must be met:

)DC(MAXLOADDISP I I I 

(2)

where IMAX(DC) is the maximum load current the IC is

guaranteed to support.

Startup into Large COUT

Multiple soft-start cycles are required for no-load startup if

COUT is greater than 15 µF. Large COUT requires light initial

load to ensure the FAN53601/11 starts appropriately. The IC

shuts down for 1.3 ms when IDISP exceeds ILIMIT for more

than 200 µs of current limit. The IC then begins a new soft-

start cycle. Since COUT retains its charge when the IC is off,

the IC reaches regulation after multiple soft-start attempts.

MODE Pin

Logic 1 on this pin forces the IC to stay in PWM Mode. A

logic 0 allows the IC to automatically switch to PFM during

light loads. If the MODE pin is toggled with a frequency

between 1.3 MHz and 1.7 MHz, the converter synchronizes

its switching frequency to four times the frequency on the

MODE pin.

The MODE pin is internally buffered with a Schmitt trigger,

which allows the MODE pin to be driven with slow rise and

fall times. An asymmetric duty cycle for frequency

synchronization is also permitted as long as the minimum

time below VIL(MAX) or above VIH(MAX) is 100 ns.

Current Limit, Fault Shutdown, and Restart

A heavy load or short circuit on the output causes the current

in the inductor to increase until a maximum current threshold

is reached in the high-side switch. Upon reaching this point,

the high-side switch turns off, preventing high currents from

causing damage. The regulator continues to limit the current

cycle-by-cycle. After 16 cycles of current limit, the regulator

triggers an over-current fault, causing the regulator to shut

down for about 1.3 ms before attempting a restart.

If the fault is caused by short circuit, the soft-start circuit

attempts to restart and produces an over-current fault after

about 200 µs, which results in a duty cycle of less than 15%,

limiting power dissipation.

The closed-loop peak-current limit is not the same as the

open-loop tested current limit, ILIM(OL), in the Electrical

Characteristics table. This is primarily due to the effect of

propagation delays of the IC current limit comparator.

Under-Voltage Lockout (UVLO)

When EN is HIGH, the under-voltage lockout keeps the part

from operating until the input supply voltage rises high

enough to properly operate. This ensures no misbehavior of

the regulator during startup or shutdown.

FAN53601 / FAN53611 • Rev. 1.8 12

FAN53601 / FAN53611 — 6 MHz 600 mA / 1 A Synchronous Buck Regulator

Thermal Shutdown (TSD)

When the die temperature increases, due to a high load

condition and/or a high ambient temperature; the output

switching is disabled until the die temperature falls sufficiently.

The junction temperature at which the thermal shutdown

activates is nominally 150°C with a 15°C hysteresis.

Minimum Off-Time Effect on Switching

Frequency

tOFF(MIN) is 40 ns. This imposes constraints on the maximum

OUT

that the FAN53601/11 can provide or the maximum

output voltage it can provide at low VIN while maintaining a

fixed switching frequency in PWM Mode.

When VIN is LOW, fixed switching is maintained as long as:

7.01 )(  SWMINOFF

OUT ft

The switching frequency drops when the regulator cannot

provide sufficient duty cycle at 6 MHz to maintain regulation.

This occurs when VOUT is 1.82 V and VIN is below 2.7 V at

high load currents (see Figure 34).

1,500

3,000

4,500

6,000

7,500

0200 400 600 800 1000

Switching Frequency (KHz)

Load Current (mA)

2.7VIN, AUTO

2.3VIN, AUTO

2.7VIN, PWM

2.3VIN, PWM

Figure 34. Frequency vs. Load Current to

Demonstrate t

OFFMIN

Effect, V

= 2.3 V and 2.7 V,

OUT

= 1.82 V, Auto Mode, FPWM Dotted

The calculation for switching frequency is given by:













MHz

fMAXSW

SW 6 ,

min )(

(3)

where:



















OUTONOUTIN

OFFOUTOUT

MAXSW VRIV RIV

nst140

)(

(4)

where:

OFF

LNDSON DCRR

LPDSON DCRR

FAN53601 / FAN53611 • Rev. 1.8 13

FAN53601 / FAN53611 — 6 MHz 600 mA / 1 A Synchronous Buck Regulator

Applications Information

Selecting the Inductor

The output inductor must meet both the required inductance

and the energy-handling capability of the application. The

inductor value affects average current limit, the PWM-to-

PFM transition point, output voltage ripple, and efficiency.

The ripple current (∆I) of the regulator is:

















 SW

OUTIN

OUT fL VV

(5)

The maximum average load current, IMAX(LOAD), is related to

the peak current limit, ILIM(PK), by the ripple current, given by:

II )PK(LIM)LOAD(MAX 



(6)

The transition between PFM and PWM operation is

determined by the point at which the inductor valley current

crosses zero. The regulator DC current when the inductor

current crosses zero, IDCM, is:

IDCM 



(7)

The FAN53601/11 is optimized for operation with L = 470 nH,

but is stable with inductances up to 1 µH (nominal). The

inductor should be rated to maintain at least 80% of its value

at ILIM(PK).

Efficiency is affected by the inductor DCR and inductance

value. Decreasing the inductor value for a given physical size

typically decreases the DCR; but because ∆I increases, the

RMS current increases, as do the core and skin effect losses.

I I 2

)DC(OUTRMS 



(8)

The increased RMS current produces higher losses through

the RDS(ON) of the IC MOSFETs, as well as the inductor DCR.

Increasing the inductor value produces lower RMS currents,

but degrades transient response. For a given physical

inductor size, increased inductance usually results in an

inductor with lower saturation current and higher DCR.

Table 1 shows the effects of inductance higher or lower than

the recommended 1 µH on regulator performance.

Output Capacitor

Table 2 suggests 0402 capacitors. 0603 capacitors may

further improve performance in that the effective capacitance

is higher. This improves transient response and output ripple.

Increasing COUT has no effect on loop stability and can

therefore be increased to reduce output voltage ripple or to

improve transient response. Output voltage ripple, ∆VOUT, is:

 





















 OUTSW

OUTSW

LOUT Cf8 1

D1D2 ESRCf

(9)

Input Capacitor

The 2.2 µF ceramic input capacitor should be placed as

close as possible between the VIN pin and GND to minimize

the parasitic inductance. If a long wire is used to bring power

to the IC, additional “bulk” capacitance (electrolytic or

tantalum) should be placed between CIN and the power

source lead to reduce the ringing that can occur between the

inductance of the power source leads and CIN.

The effective capacitance value decreases as VIN increases

due to DC bias effects.

Table 1. Effects of Changes in Inductor Value (from 470 nH Recommended Value) on Regulator Performance

Inductor Value

IMAX(LOAD)

∆VOUT

Transient Response

Increase

Decrease

Degraded

Decrease

Increase

Improved

Table 2. Recommended Passive Components and their Variation Due to DC Bias

Component

Description

Vendor

Min.

Typ.

Max.

470 nH,

2012,90 mΩ,

1.1 A

Murata LQM21PNR47MC0

Murata LQM21PNR54MG0

Hitachi Metals HLSI 201210R47

300 nH

470 nH

520 nH

CIN

2.2 µF, 6.3 V,

X5R, 0402

Murata or Equivalent GRM155R60J225ME15

GRM188R60J225KE19D

1.0 µF

2.2 µF

COUT

4.7 µF, X5R,

0402

Murata or Equivalent GRM155R60G475M

GRM155R60E475ME760

1.6 µF

4.7 µF

FAN53601 / FAN53611 • Rev. 1.8 14

FAN53601 / FAN53611 — 6 MHz 600 mA / 1 A Synchronous Buck Regulator

PCB Layout Guidelines

There are only three external components: the inductor and

the input and output capacitors. For any buck switcher IC,

including the FAN53601/11, it is important to place a low-ESR

input capacitor very close to the IC, as shown in Figure 35.

The input capacitor ensures good input decoupling, which

helps reduce noise appearing at the output terminals and

ensures that the control sections of the IC do not behave

erratically due to excessive noise. This reduces switching

cycle jitter and ensures good overall performance. It is

important to place the common GND of CIN and COUT as close

as possible to the C2 terminal. There is some flexibility in

moving the inductor further away from the IC; in that case,

VOUT should be considered at the COUT terminal.

Figure 35. PCB Layout Guidance

The following information applies to the WLCSP package dimensions on the next page:

Product-Specific Dimensions

1.160 ±0.030

0.860 ±0.030

0.230

0.180

SEATING PLANE

0.06 C

0.05 C

SIDE VIEWS NOTES:

A. NO JEDEC REGISTRATION APPLIES.

B. DIMENSIONS ARE IN MILLIMETERS.

C. DIMENSIONS AND TOLERANCES PER

ASMEY14.5M, 2009.

D. DATUM C, THE SEATING PLANE IS DEFINED

BY THE SPHERICAL CROWNS OF THE BALLS.

E. PACKAGE TYPICAL HEIGHT IS 586 MICRONS

±39 MICRONS (547-625 MICRONS).

F. FOR DIMENSIONS D, E, X, AND Y, SEE

PRODUCT DATASHEET.

G. DRAWING FILENAME: MKT-UC006ACrev6.

BOTTOM VIEW

TOP VIEW RECOMMENDED LAND PATTERN

(NSMD PAD TYPE)

BALL A1

INDEX AREA

0.03 C

0.208±0.021

0.378±0.018

0.40

0.005 C A B

(X) +/-0.015

(Y) +/-0.015

Ø0.260±0.010

0.40

F0.40

(Ø0.20)

Bottom of Cu Pad

(Ø0.30)

Solder Mask

Opening

0.586±0.039

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