S-8550AA-M5T1G - Seiko Instruments, Inc.

Rev.2.1_01

STEP-DOWN, BUILT-IN FET, SYNCHRONOUS

RECTIFICATION, PWM CONTROL SWITCHING REGULATORS

S-8550/8551 Series

Seiko Instruments Inc. 1

The S-8550/8551 Series is a CMOS synchronous rectification step-down

switching regulator which mainly consists of a reference voltage circuit, an

oscillator, an error amplifier, a phase compensation circuit, a PWM controller, an

under voltage lockout circuit (UVLO), a current limit circuit, and a power MOS

FET. The oscillation frequency is high at 1.2 MHz, so a high efficiency, large

output current, step-down switching regulator can be achieved by using small

external parts.

The built-in synchronous rectification circuit makes achieving high efficiency

easier compared with conventional step-down switching regulators. A ceramic

capacitor can be used as an output capacitor. High-density mounting is

supported by adopting a small SOT-23-5 package.

The S-8550 and S-8551 Series are offered according to different pin configuration.

 Features

• Oscillation frequency : 1.2 MHz

• Input voltage range : 2.0 to 5.5 V

• Output voltage range : Arbitrarily settable by external output voltage setting resistor

• Output current : 600 mA

• Reference voltage : 0.6 V ±2.0%

• Efficiency : 92%

• Soft-start function : 1 ms typ.

• Shutdown function : Shutdown current consumption : 1.0 µA max.

• Built-in current limit circuit

• Pch power MOS FET on-resistance : 0.4 Ω typ.

• Nch power MOS FET on-resistance : 0.3 Ω typ.

• Constant continuous mode operation (no light load mode)

• Small package : SOT-23-5

• Lead-free products

 Applications

• Mobile devices, such as mobile phones, Bluetooth devices, wireless devices, digital audio players, digital still

cameras, portable DVD players, and portable CD players

 Package

Drawing Code

Package Name Package Tape Reel

SOT-23-5 MP005-A MP005-A MP005-A

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

S-8550/8551 Series Rev.2.1_01

2 Seiko Instruments Inc.

 Block Diagram

ON/OFF

−

VIN

CONT

VSS

FB1

FB2

OUT

Reference

voltage PWM comparator

PWM control

circuit

UVLO

circuit

ON/OFF

circuit

IC internal

power supply

Current limit

circuit

Error amplifier

angu

ar wave

generation

circuit

*1. Parasitic diode

Figure 1

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

Rev.2.1_01 S-8550/8551 Series

Seiko Instruments Inc. 3

 Product Name Structure

Product name

S-855 x A A - M5T1

Package name (abbreviation) and packing specification*1

M5T1 : SOT-23-5, tape

Oscillation frequency

A : 1.2 MHz

Pin configuration setting*2

0 : Pin configuration 1

1 : Pin configuration 2

*1. Refer to the taping specifications at the end of this book.

*2. Refer to Table 1 and Table 2 of “ Pin Configurations”.

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

S-8550/8551 Series Rev.2.1_01

4 Seiko Instruments Inc.

 Pin Configurations

Table 1 S-8550 Series (Pin Configuration 1)

Pin No. Symbol Description

1 VIN IC power supply pin

2 VSS GND pin

ON/OFF

Shutdown pin

“H” : Power on (normal operation)

“L” : Power off (standby)

4 FB Output voltage feedback pin

5 CONT External inductor connection pin

SOT-23-5

Top view

5 4

3 2 1

Figure 2

Table 2 S-8551 Series (Pin Configuration 2)

Pin No. Symbol Description

ON/OFF

Shutdown pin

“H” : Power on (normal operation)

“L” : Power off (standby)

2 VSS GND pin

3 CONT External inductor connection pin

4 VIN IC power supply pin

5 FB Output voltage feedback pin

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

Rev.2.1_01 S-8550/8551 Series

Seiko Instruments Inc. 5

 Absolute Maximum Ratings

Table 3 Absolute Maximum Ratings

(Unless otherwise specified: Ta = 25°C, VSS = 0 V)

Parameter Symbol Absolute Maximum Rating Unit

VIN pin voltage VIN V

SS − 0.3 to VSS + 6.0 V

FB pin voltage VFB V

SS − 0.3 to VIN + 0.3 V

CONT pin voltage VCONT V

SS − 0.3 to VIN + 0.3 V

ON/OFF pin voltage VON/OFF V

SS − 0.3 to VIN + 0.3 V

CONT pin current ICONT 1300 mA

Power dissipation PD 600*1 mW

Operating temperature Topr −40 to +85 °C

Storage temperature Tstg −40 to +125 °C

*1. When mounted on printed circuit board

[Mounted board]

(1) Board size: 114.3 mm × 76.2 mm × t1.6 mm

(2) Board name: JEDEC STANDARD51-7

Caution 1. The absolute maximum ratings are rated values exceeding which the product could suffer

physical damage. These values must therefore not be exceeded under any conditions.

2. Since this IC has a built-in power MOS FET, make sure that dissipation of the power MOS FET

does not exceed the allowable power dissipation of the package. (Refer to Figure 3.)

Generally, dissipation of a switching regulator can be calculated by the following equation.

Dissipation = (100 (%) − efficiency (%)) / efficiency (%) × output voltage × load current

The greater part of dissipation depends on the built-in power MOS FET, however, dissipation

of the inductor is also included.

In addition, since power dissipation of the package also changes according to a mounting

board or a mounting state, fully check them using an actually mounted mode.

400

Power dissipation (PD) [mW]

Ambient temperature (Ta) [°C]

200

500

300

100

600

700

50 100 150

Figure 3 Power Dissipation of Package (Mounted on Board)

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

S-8550/8551 Series Rev.2.1_01

6 Seiko Instruments Inc.

 Electrical Characteristics

Table 4 Electrical Characteristics

(Unless otherwise specified: VIN = 3.6 V, VOUT = 1.8 V (the conditions in Table 5), Ta = 25°C)

Parameter Symbol Conditions Min. Typ. Max. Unit

Test

Circuit

Operating input voltage VIN  2.0  5.5 V 2

Output voltage range*1 VOUT V

IN = VOUT(S) + 0.4 V to 5.5 V 1.1  4.0 V 2

FB voltage VFB V

IN = VOUT(S) + 0.4 V to 5.5 V 0.588 0.6 0.612 V 2

FB voltage temperature

coefficient

∆VFB

∆Ta

Ta = −40°C to +85°C  ±100  ppm/°C 2

FB pin input current IFB V

IN = 2.0 V to 5.5 V, FB pin −0.1  +0.1 µA 1

Current consumption

during shutdown ISSS VIN = 2.0 V to 5.5 V,

VON/OFF = 0 V   1.0 µA 1

Current consumption 1 ISS1 fosc = 1.2 MHz, no external parts,

VFB = VFB(S) × 1.1 V  200 400 µA 1

RPFET I

CONT = 100 mA  0.4 0.6 Power MOS FET

on-resistance RNFET I

CONT = −100 mA  0.3 0.5 Ω 1

Power MOS FET

leakage current ILSW VIN = 2.0 V to 5.5 V,

VON/OFF = 0 V, VCONT = 0 or 3.6 V  ±0.01 ±0.5 µA 1

Limit current ILIM  800 1000 1200 mA 1

Oscillation frequency fosc  1.02 1.2 1.38 MHz 2

Soft-start time tSS Time required to reach 90% of

VOUT(S) 0.7 1.0 1.3 ms 2

High level input voltage VSH V

IN = 2.0 V to 5.5 V, ON/OFF pin 0.9   V 2

Low level input voltage VSL V

IN = 2.0 V to 5.5 V, ON/OFF pin   0.3 V 2

High level input current ISH V

IN = 2.0 V to 5.5 V, ON/OFF pin −0.1  0.1 µA 1

Low level input current ISL V

IN = 2.0 V to 5.5 V, ON/OFF pin −0.1  0.1 µA 1

UVLO detection voltage

VUVLO  1.4 1.6 1.78 V 2

*1. V

OUT(S) is the output voltage set value, and VOUT is the typ. value of the actual output voltage.

OUT(S) can be set depending on the ratio between the VFB value and output voltage set resistors (RFB1, RFB2).

For details, refer to “ External Parts Selection”.

 External Parts When Measuring Electrical Characteristics

Table 5 External Parts

Element Name Symbol Constant Manufacturer Part Number

Inductor L 3.3 µH Taiyo Yuden Co., Ltd. NR4018T3R3M

Input capacitor CIN 4.7 µF TDK Corporation C3216X7R1E475K

Output capacitor COUT 10 µF TDK Corporation C3216X7R1C106K

Output voltage set resistor 1 RFB1 36 kΩ Rohm Co., Ltd. MCR03 Series 3602

Output voltage set resistor 2 RFB2 18 kΩ Rohm Co., Ltd. MCR03 Series 1802

Phase compensation capacitor CFB 68 pF Murata Manufacturing Co., Ltd. GRM1882C1H680J

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

Rev.2.1_01 S-8550/8551 Series

Seiko Instruments Inc. 7

 Test Circuits

S-855xA

ON/OFF

↓

CONT

VSS

VIN

Figure 4

S-855xA

ON/OFF

CONT

VSS

VIN

V↓I

OUT

FB1

FB2

Figure 5

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

S-8550/8551 Series Rev.2.1_01

8 Seiko Instruments Inc.

 Operation

1. Synchronous rectification PWM control step-down switching regulator

1.1 Synchronous rectification

The synchronous rectification method lowers voltage drop to greatly reduce power dissipation since an Nch

power MOS FET, having resistance much lower than conventional switching regulators, is used.

In conventional switching regulators, current flows in the diode connected between the GND and CONT pins

when the Pch power MOS FET is off. The forward drop voltage (Vf) of such diodes is large, between 0.3 to

0.7 V, so the power dissipation used to be very large. Synchronous rectification ultra-low resistance Nch

transistors repeat on and off, in synchronization with the operation of the Pch driver, in the reverse cycle of

the Pch driver. Moreover, the built-in P and N through prevention circuit helps much reduction of power

consumption during operation.

1.2 PWM control

The S-8550/8551 Series is a switching regulator using a pulse width modulation method (PWM) and features

low current consumption.

In conventional PWM control switching regulators, pulses are skipped when the output load current is low,

causing a fluctuation in the ripple frequency of the output voltage, resulting in an increase in the ripple

voltage.

In the S-8550/8551 Series, the switching frequency does not change, although the pulse width changes from

0 to 100% corresponding to each load current. The ripple voltage generated from switching can thus be

removed easily using a filter because the switching frequency is constant.

2. Soft-start function

The soft-start circuit built in the S-8550/8551 Series controls the rush current and the overshoot of the output

voltage when powering on, the ON/OFF pin is switched from the “L” level to the “H” level, or the UVLO operation

is released. A reference voltage adjustment method is adopted as the soft-start method.

3. Shutdown pin

This pin stops or starts step-up operations.

Switching the shutdown pin to the “L” level stops operation of all the internal circuits and reduces the current

consumption significantly. DO NOT use the shutdown pin in a floating state because it is not pulled up or

pulled down internally. DO NOT apply voltage of between 0.3 and 0.9 V to the shutdown pin because applying

such a voltage increases the current consumption. If the shutdown pin is not used, connect it to the VIN pin.

Table 6

Shutdown Pin CR Oscillation Circuit Output Voltage

“H” Operates Set value

“L” Stops Hi-Z

VIN

ON/OFF

VSS

Figure 6

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

Rev.2.1_01 S-8550/8551 Series

Seiko Instruments Inc. 9

4. Current limit circuit

A current limit circuit is built in the S-8550/8551 Series.

The current limit circuit monitors the current that flows in the Pch power MOS FET and limits current in order to

prevent thermal destruction of the IC due to an overload or magnetic saturation of the inductor.

When a current exceeding the current limit detection value flows in the Pch power MOS FET, the current limit

circuit operates and turns off the Pch power MOS FET since the current limit detection until one clock of the

oscillator ends. The Pch power MOS FET is turned on in the next clock and the current limit circuit resumes

current detection operation. If the value of the current that flows in the Pch power MOS FET remains the

current limit detection value or more, the current limit circuit functions again and the same operation is repeated.

Once the value of the current that flows in the Pch power MOS FET is lowered up to the specified value, the

normal operation status restores. A slight overshoot is generated in the output voltage when the current limit is

released.

The current limit detection value is fixed to 1 A (typ.) in the IC. If the time taken for the current limit to be

detected is shorter than the time required for the current limit circuit in the IC to detect, the current value that is

actually limited increases. Generally, the voltage difference between the VIN and VOUT pins is large, the

current limit detection status is reached faster and the current value increases.

5. 100% duty cycle

The S-8550/8551 Series operates up to the maximum duty cycle at 100%. Even when the input voltage is

lowered up to the output voltage value set using the external output voltage setting resistor, the Pch power MOS

FET is kept on and current can be supplied to the load. The output voltage at this time is the input voltage from

which the voltage drop due to the direct resistance of the inductor and the on-resistance of the Pch power MOS

FET are subtracted.

6. UVLO function

The S-8550/8551 Series includes a UVLO (under-voltage lockout) circuit to prevent the IC from malfunctioning

due to a transient status when power is applied or a momentary drop of the supply voltage. When UVLO is in

the detection state, the Pch and Nch power MOS FETs stop switching operation, and the CONT pin become

Hi-Z. Once the S-8550/8551 is in the UVLO detection status, the soft-start function is reset, but the soft-start

operates by the releasing operation of UVLO after that.

Note that the other internal circuits operate normally and that the status is different from the power-off status.

The hysteresis width is set for the UVLO circuit to prevent a malfunction due to a noise that is generated in the

input voltage. A voltage about 150 mV (typ.) higher than the UVLO detection voltage is the release voltage.

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

S-8550/8551 Series Rev.2.1_01

10 Seiko Instruments Inc.

 Operation Principle

The S-8550/8551 Series is a step-down synchronous rectification switching regulator based on constant PWM

control. Figure 7 shows the basic circuit diagram.

A step-down switching regulator starts current supply by the input voltage (VIN) when the Pch power MOS FET is

turned on and holds energy in the inductor at the same time. When the Pch power MOS FET is turned off, the

current held in the inductor is released. The released current flows in the smoothing circuit, with the energy loss

held minimum, supplies the output voltage (VOUT) lower than VIN. VOUT is kept constant by controlling the

switching frequency (fosc) and ON time (ton). With the PWM control method, VOUT is made constant by controlling

the ON time with fOSC unchanged.

Control

circuit

Pch power MOS FET

Nch power MOS FET

OUT

Figure 7 Basic Circuit Drawing of Step-down Switching Regulator

1. Continuous mode

The following explains how the current flows to the inductor when the step-down operation is constant and

stable.

When the Pch power MOS FET is turned on, current I1 flows in the direction shown by the arrow in Figure 7,

and energy is stored in the inductor (L). When the output capacitor (COUT) is charged, supply of the output

current (IOUT) is started at the same time. The inductor current (IL) gradually increases in proportion to the ON

time (tON) of the Pch power MOS FET as shown in Figure 8 (changes from IL min. to IL max.). When the Pch

power MOS FET is turned off, the Nch power MOS FET is turned on and IL tries to hold IL max. Consequently,

current I2 flows in the direction shown by the arrow in Figure 7. As a result, IL gradually decreases and

reaches IL min. when the OFF time (tOFF) has elapsed. When tOFF has elapsed, the Nch power MOS FET is

turned off and the next cycle is entered. The above sequence is repeated.

As explained in the above, the continuous mode refers to the operation in the current cycle in which IL linearly

changes from IL min. to IL max. Even if IL min. is less than 0 A, IL min. keeps flowing (backflow current flows).

ton toff

T = 1/fOSC

IL max.

IL min.

Figure 8 Continuous Mode (Current Cycle of Inductor Current (IL))

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SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

Rev.2.1_01 S-8550/8551 Series

Seiko Instruments Inc. 11

2. Backflow current

The S-8550/8551 Series performs PWM synchronous rectification even if IL min. is less than 0 A, so a backflow

current is generated in VIN and the backflow current becomes maximum when no load is applied (see Figure 9).

Use the following equation to calculate the maximum backflow current value, which should be taken into

consideration when designing.

Duty (IOUT = 0) = VOUT / VIN

Example : VIN = 3.6 V, VOUT = 1.8 V …… Duty = 50%

∆IL = ∆V / L × ton = (VIN − VOUT) × Duty / (L × fOSC)

Example : VIN = 3.6 V, VOUT = 1.8 V, fOSC = 1.2 MHz, L = 3.3 µH …… ∆IL = 227 mA

L max. = ∆IL / 2 = 113.5 mA, IL min. = −∆IL / 2 = −113.5 mA

The current value waveform of the inductor is a triangular wave, of which the maximum value is IL max. and the

minimum value is IL min. (negative value), and the negative value (the portion marked by diagonal lines in

Figure 9) backflows when no load is applied (see Figure 9).

If about 113.5 mA of IOUT flows in the above conditions, the minimum value (IL min.) of the triangular wave is

made 0 mA and no backflow current flows.

When an input capacitor (CIN) is connected, the backflow current is absorbed by CIN, thus reducing the backflow

current to flow in the power supply. Be sure to connect an input capacitor to reduce backflow current to the

power supply (see Figure 10).

The above presents the conditions required to prevent backflow current from flowing, which is only a guideline.

Perform sufficient confirmation using an actual application.

Inductor current with no load Inductor current when load is a

current of 113.5 mA

Backflow

current

−113.5 mA

113.5 mA

IL min.

IL max.

∆IL

0 mA

Backflow current = 0 mA

0 mA

OUT

113.5 mA

OUT

227 mA

IL min.

IL max.

∆IL

Figure 9 Example of Conditions to Prevent Backflow Current from Flowing

VOUT

VIN

CONT

Backflow current

Inductor

current IL

CIN

VIN

Figure 10 Backflow Current

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

S-8550/8551 Series Rev.2.1_01

12 Seiko Instruments Inc.

 External Parts Selection

1. Inductor

The inductance (L value) has a strong influence on the maximum output current (IOUT) and efficiency (η).

The peak current (IPK) increases by decreasing L and the stability of the circuit improves and IOUT increases. If

L is decreased further, the current drive capability of the external transistor is insufficient and IOUT decreases.

If the L value is increased, the loss due to IPK of the power MOS FET decreases and the efficiency becomes

maximum at a certain L value. Further increasing L decreases the efficiency due to the increased loss of the

DC resistance of the inductor.

The recommended L value for the S-8550/8551 Series is 3.3 µH.

When selecting an inductor, note the allowable current of the inductor. If a current exceeding this allowable

current flows through the inductor, magnetic saturation occurs, substantially lowering the efficiency.

Therefore, select an inductor so that IPK does not exceed the allowable current. IPK is expressed by the

following equations in the discontinuous mode and continuous mode.

2 × f

OSC

× L × V

= I

OUT

+ V

OUT

× (V

− V

OUT

)

fOSC = Oscillation frequency

Table 7 Typical Inductors

Manufacturer Part Number L Value DC

Resistance Rated Current Dimensions

(L × W × H) [mm]

NR4018T3R3M 3.3 µH 0.07 Ω max. 1.23 A max. 4.0 × 4.0 × 1.8

Taiyo Yuden Co., Ltd.

NR3012T3R3M 3.3 µH 0.1 Ω max. 0.91 A max. 3.0 × 3.0 × 1.2

CDRH3D16/HP-3R3 3.3 µH 0.085 Ω max. 1.40 A max. 4.0 × 4.0 × 1.8

Sumida Corporation

CDRH2D11/HP-3R3 3.3 µH 0.173 Ω max. 0.9 A max. 3.2 × 3.2 × 1.2

VLF4012AT-3R3M 3.3 µH 0.12 Ω max. 1.3 A max. 3.7 × 3.5 × 1.2

TDK Corporation

VLF3010AT-3R3M 3.3 µH 0.17 Ω max. 0.87 A max. 2.6 × 2.8 × 1.0

MIP3226D3R3M 3.3 µH 0.104 Ω max. 1.2 A max. 3.2 × 2.6 × 1.0

FDK Corporation

MIPS2520D3R3M 3.3 µH 0.156 Ω max. 1.0 A max. 2.5 × 2.0 × 1.0

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

Rev.2.1_01 S-8550/8551 Series

Seiko Instruments Inc. 13

2. Capacitors (CIN, COUT)

A ceramic capacitor can be used for the input (CIN) and output (COUT) sides. CIN lowers the power supply

impedance and averages the input current to improve efficiency. Select CIN according to the impedance of the

power supply to be used. The recommended capacitance is 4.7 µF for the S-8550/8551 Series when a general

lithium ion rechargeable battery is used.

Select as COUT a capacitor with large capacitance and small ESR for smoothing the ripple voltage. The

optimum capacitor selection depends on the L value, capacitance value, wiring, and application (output load).

Select COUT after sufficient evaluation under actual use conditions.

3. Output voltage setting resistors (RFB1, RFB2), capacitor for phase compensation (CFB)

With the S-8550/8551 Series, VOUT can be set to any value by external divider resistors. Connect the divider

resistors across the VOUT and VSS pins. Because VFB = 0.6 V typ., VOUT can be calculated by this equation.

FB2

OUT

= (R

FB1

+ R

FB2

) × 0.6

Connect divider resistors RFB1 and RFB2 as close to the IC to minimize effects from of noise. If noise does have

an effect, adjust the values of RFB1 and RFB2 so that RFB1 + RFB2 < 100 kΩ.

CFB connected in parallel with RFB1 is a capacitor for phase compensation.

By setting the zero point (the phase feedback) by adding capacitor CFB to output voltage setting resistor RFB1 in

parallel, the feedback loop gains the phase margin. As a result, the stability can be obtained. In principle, to use

the portion how much the phase has feed back by the zero point effectively, define CFB referring to the following

equation.

kHz70xRxx2

1FB

FB π

≅

This equation is the reference.

The followings are explanation regarding the proper setting.

To use the portion how much the phase has feed back by the zero point effectively, set RFB1 and CFB so that the

zero point goes into the higher frequency than the pole frequency of L and COUT. The following equations are the

pole frequency of L and COUT and the zero point frequency by CFB and RFB1.

OUTCxLxx2

fpole π

≅

FB1FB

zero CxRxx2

fπ

≅

The transient response can be improved by setting the zero point frequency in the range of lower frequency.

However, since the gain becomes higher in the range of high frequency, the total phase of feedback loop delays

180° or more by setting the zero point frequency in the significantly lower range. As a result, the gain cannot be

0 dB or lower in the frequency range thus the operation might be unstable. Determine the proper value after the

sufficient evaluation under the actual condition.

The typical constants by our evaluation are in Table 8.

Table 8 Constant for External Parts

VOUT(s) [V] RFB1 [kΩ] RFB2 [kΩ] CFB [pF] L [µH]*1 C

OUT [µF]*1

1.1 36 43 56 3.3 10

1.8 36 18 68 3.3 10

3.3 36 8 120 3.3 10

4.0 51 9 100 3.3 10

*1. The recommended parts in Table 5

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BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

S-8550/8551 Series Rev.2.1_01

14 Seiko Instruments Inc.

 Standard Circuit

ON/OFF

−

VIN

CONT

VSS

FB1

FB2

OUT

4.7

3.3

36 k

Ω

18 k

Ω

68 pF

1.0

Reference

voltage

PWM comparator

PWM control

circuit

UVLO circuit

ON/OFF

circuit

IC internal

power supply

Current limit

circuit

Error amplifier

Ground point

Triangular wave

generation

circuit

*1. Parasitic diode

Figure 11

Caution The above connection diagram and constant will not guarantee successful operation. Perform

thorough evaluation using an actual application to set the constants.

 Precaution

• Mount external capacitors, diodes, and inductor as close as possible to the IC.

• Characteristics ripple voltage and spike noise occur in IC containing switching regulators. Moreover rush current

flows at the time of a power supply injection. Because these largely depend on the inductor, the capacitor and

impedance of power supply used, fully check them using an actually mounted model.

• The 1.0 µF capacitance connected between the VIN and VSS pins is a bypass capacitor. It stabilizes the power

supply in the IC when application is used with a heavy load, and thus effectively works for stable switching

regulator operation. Allocate the bypass capacitor as close to the IC as possible, prioritized over other parts.

• Although the IC contains a static electricity protection circuit, static electricity or voltage that exceeds the limit of

the protection circuit should not be applied.

• The power dissipation of the IC greatly varies depending on the size and material of the board to be connected.

Perform sufficient evaluation using an actual application before designing.

• Seiko Instruments Inc. assumes no responsibility for the way in which this IC is used on products created using

this IC or for the specifications of that product, nor does Seiko Instruments Inc. assume any responsibility for any

infringement of patents or copyrights by products that include this IC either in Japan or in other countries.

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

Rev.2.1_01 S-8550/8551 Series

Seiko Instruments Inc. 15

 Characteristics (Typical Data)

1. Example of Major Power Supply Dependence Characteristics (Ta = 25°C)

1. 1 Current consumption 1 (I

SS1

) vs. Input voltage (V

)

1. 2 Current consumption during shutdown (I

SSS

) vs. Input voltage (V

)

2.0 4.0 5.0 5.5

SS1

[µA]

500

400

300

200

100

[V]

2.5 3.0 3.5 4.5

2.0 4.0 5.0 5.5

SSS

[µA]

1.0

0.8

0.6

0.4

0.2

[V]

2.5 3.0 3.5 4.5

1. 3 Oscillation frequency (f

osc

) vs. Input voltage (V

)

1. 4 Soft-start time (tSS) vs. Input voltage (VIN)

2.0 4.0 5.0 5.5

OSC

[MHz]

1.38

1.30

1.18

1.10

1.02

[V]

2.5 3.0 3.5 4.5

1.06

1.14

1.22

1.26

1.34

2.0 4.0 5.0 5.5

[ms]

1.3

1.1

1.0

0.9

0.7

[V]

2.5 3.0 3.5 4.5

0.8

1.2

1. 5 Power MOS FET on-resistance (R

FET

) vs. Input voltage (V

)

1. 6 Power MOS FET leakage current (I

LSW

) vs. Input voltage (V

)

2.0 4.0 5.0 5.5

FET

[Ω]

0.8

0.6

0.5

0.4

0.2

[V]

2.5 3.0 3.5 4.5

0.3

0.7

Nch

Pch

2.0 4.0 5.0 5.5

LSW

[µA]

0.5

0.1

−0.1

−0.5

[V]

2.5 3.0 3.5 4.5

−0.4

0.4

Nch

Pch

0.2

0.3

−0.2

−0.3

1. 7 ON/OFF pin input voltage“H” (V

) vs. Input voltage (V

)

1. 8 ON/OFF pin input voltage“L” (V

) vs. Input voltage (V

)

2.0 4.0 5.0 5.5

[V]

0.9

0.6

0.3

[V]

2.5 3.0 3.5 4.5

0.7

0.8

0.5

0.4

2.0 4.0 5.0 5.5

[V]

0.9

0.6

0.3

[V]

2.5 3.0 3.5 4.5

0.7

0.8

0.5

0.4

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

S-8550/8551 Series Rev.2.1_01

16 Seiko Instruments Inc.

1. 9 FB voltage (VFB) vs. Input voltage (VIN)

2.0 4.0 5.0 5.5

[mV]

612

600

588

[V]

2.5 3.0 3.5 4.5

604

608

596

592

2. Example of Major Temperature Characteristics (Ta = −40 to 85°C)

2. 1 Current consumption 1 (I

SS1

) vs. Temperature (Ta)

2. 2 Current consumption during shutdown (I

SSS

) vs. Temperature (Ta)

−40 75 85

SS1

[

µA

]

500

−25 0 25 50

300

400

200

100

Ta [ °C]

VIN = 5.5 V

VIN = 3.6 V

VIN = 2.0 V

−40 75 85

SSS

[

µA

]

1.0

−25 0 25 50

0.6

0.8

0.4

0.2

Ta [ °C]

VIN = 5.5 V

VIN = 3.6 V

VIN = 2.0 V

2. 3 Oscillation frequency (f

osc

) vs. Temperature (Ta)

2. 4 Soft-start time (tSS) vs. Temperature (Ta)

−40 75 85

fOSC

[MHz]

1.32

1.08

−25 0 25 50

1.28

1.20

1.16

Ta [ °C]

= 5.5 V

= 3.6 V

= 2.0 V

1.12

1.24

−40 75 85

tSS

[ms]

1.3

0.7

−25 0 25 50

1.1

1.0

0.9

Ta [ °C]

= 5.5 V

= 3.6 V

= 2.0 V

0.8

1.2

2. 5 Power MOS FET on-resistance (R

FET

) vs. Temperature (Ta)

2. 6 Power MOS FET leakage current (I

LSW

) vs. Temperature (Ta)

−40 75 85

FET

[Ω]

0.8

0.2

−25 0 25 50

Ta [ °C]

VIN = 5.5 V

VIN = 3.6 V

VIN = 2.0 V

VIN = 5.5 V

VIN = 3.6 V

VIN = 2.0 V

Pch Nch

0.6

0.5

0.4

0.3

0.7

−40 75 85

LSW

[µA]

0.5

−0.5

−25 0 25 50

Ta [ °C]

VIN = 5.5 V

Pch

Nch

0.1

−0.1

−0.4

0.4

0.2

0.3

−0.2

−0.3

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

Rev.2.1_01 S-8550/8551 Series

Seiko Instruments Inc. 17

2. 7 ON/OFF pin input voltage“H” (V

) vs. Temperature (Ta)

2. 8 ON/OFF pin input voltage“L” (V

) vs. Temperature (Ta)

−40 75 85

VSH

[V]

0.9

0.3

−25 0 25 50

Ta [ °C]

0.6

0.7

0.8

0.5

0.4

= 3.6 V

= 5.5 V

= 2.0 V

−40 75 85

VSL

[V]

0.9

0.3

−25 0 25 50

Ta [ °C]

0.6

0.7

0.8

0.5

0.4

= 5.5 V

= 3.6 V

= 2.0 V

2. 9 UVLO detection voltage (V

UVLO

) vs. Temperature (Ta)

2. 10 FB voltage (VFB) vs. Temperature (Ta)

−40 75 85

UVLO

[V]

1.80

1.40

−25 0 25 50

Ta [ °C]

1.60

1.70

1.75

1.55

1.45

1.50

1.65

−40 75 85

[mV]

612

588

−25 0 25 50

Ta [ °C]

600

604

608

596

592

VIN = 5.5 V

VIN = 3.6 V

VIN = 2.0 V

3. Examples of Transient Response Characteristics

(Unless otherwise specified, the used parts are ones shown in



External Parts When Measuring Electrical Characteristics

3. 1 Powering ON (VOUT = 1.8 V, VIN = 0 V → 3.6 V, Ta = 25°C)

(1) IOUT = 1 mA (2) IOUT = 600 mA

−0.2 0.6 1.0 1.6

, V

OUT

[V]

−1

t [ms]

[A]

0.6

0.2

0.4

−0.2

0 0.2 0.4 0.8

OUT

1.2 1.4

−0.2 0.6 1.0 1.6

VIN, VOUT [V]

−1

t [ms]

IL [A]

1.5

0.5

1.0

−0.5

0 0.2 0.4 0.8

1.2 1.4

OUT

3. 2 Shutdown pin response (VOUT = 1.8 V, VIN = 3.6 V, VON/OFF = 0 V → 3.6 V, Ta = 25°C)

(1) IOUT = 1 mA (2) IOUT = 600 mA

−0.2 0.6 1.0 1.6

ON/OFF

, V

OUT

[V]

−1

t [ms]

[A]

0.6

0.2

0.4

−0.2

0 0.2 0.4 0.8

1.2 1.4

OUT

ON/OFF

−0.2 0.6 1.0 1.6

VON/OFF, VOUT [V]

−1

t [ms]

IL [A]

1.5

0.5

1.0

−0.5

0 0.2 0.4 0.8

1.2 1.4

OUT

ON/OFF

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

S-8550/8551 Series Rev.2.1_01

18 Seiko Instruments Inc.

3. 3 Power supply fluctuations (VOUT = 1.8 V, Ta = 25°C)

(1) IOUT = 1 mA, VIN = 2.6 V → 3.6 V → 2.6 V (2) IOUT = 600 mA, VIN = 2.6 V → 3.6 V → 2.6 V

−0.1 0.3 0.5 0.7

OUT

[V]

2.2

2.0

1.8

1.6

1.4

t [ms]

[V]

3.5

2.5

1.5

0.5

4.5

0 0.1 0.2 0.4 0.6

OUT

−0.1 0.3 0.5 0.7

VOUT [V]

2.2

2.0

1.8

1.6

1.4

t [ms]

VIN [V]

3.5

2.5

1.5

0.5

4.5

0 0.1 0.2 0.4 0.6

OUT

3. 4 Load fluctuations (VOUT = 1.8 V, VIN = 3.6 V, Ta = 25°C)

(1) IOUT = 0.1 mA → 100 mA → 0.1 mA (2) IOUT = 0.1 mA → 300 mA → 0.1 mA

−0.1 0.3 0.5 0.7

OUT

[V]

1.90

1.85

1.80

1.75

1.70

t [ms]

OUT

[mA]

200

100

−100

400

0 0.1 0.2 0.4 0.6

OUT

300

−0.1 0.3 0.5 0.7

VOUT [V]

1.90

1.85

1.80

1.75

1.70

t [ms]

IOUT [mA]

200

100

−100

400

0 0.1 0.2 0.4 0.6

300

OUT

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

Rev.2.1_01 S-8550/8551 Series

Seiko Instruments Inc. 19

 Reference Data

1. Reference data for external parts

Properties of External Parts

Element Name Product Name Manufacture Characteristics

Inductor NR4018T3R3M

Taiyo Yuden Co., Ltd 3.3 µH, DCRMAX = 0.07 Ω, IMAX = 1.23 A

Input capacitor C3216X7R1E475K TDK Corporation 4.7 µF

Output capacitor C3216X7R1C106K TDK Corporation 10 µF

Caution The values of the external parts are based on the materials provided by each manufacturer. However,

consider the characteristics of the original materials when using the above products.

2. Output current (I

OUT

) vs. Efficiency (

) Characteristics and Output current (I

OUT

) vs. Output voltage (V

OUT

) Characteristics

2. 1 VOUT = 1.1 V (RFB1 = 36 kΩ, RFB2 = 43 kΩ)

(1) Output current (IOUT) vs. Efficiency (η) (2) Output current (IOUT) vs. Output voltage (VOUT)

0 1000

η [%]

100

1 10 100

OUT

[mA]

90 VIN = 2.0 V

VIN = 3.6 V

VIN = 5.5 V

0 1000

VOUT [V]

1.3

0.9

1 10 100

OUT

[mA]

1.1

1.2

1.0

VIN = 5.5 V

VIN = 3.6 V

VIN = 2.0 V

2. 2 VOUT = 1.8 V (RFB1 = 36 kΩ, RFB2 = 18 kΩ)

(1) Output current (IOUT) vs. Efficiency (η) (2) Output current (IOUT) vs. Output voltage (VOUT)

0 1000

η [%]

100

1 10 100

IOUT [mA]

90 V

= 2.2 V

= 3.6 V

= 5.5 V

0 1000

OUT

[V]

2.0

1.6

1 10 100

IOUT [mA]

1.8

1.9

1.7

= 5.5 V

= 3.6 V

= 2.0 V

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

S-8550/8551 Series Rev.2.1_01

20 Seiko Instruments Inc.

2. 3 VOUT = 3.3 V (RFB1 = 36 kΩ, RFB2 = 8 kΩ)

(1) Output current (IOUT) vs. Efficiency (η) (2) Output current (IOUT) vs. Output voltage (VOUT)

0 1000

η [%]

100

1 10 100

IOUT [mA]

90 V

= 3.7 V

= 5.5 V

0 1000

OUT

[V]

3.5

3.1

1 10 100

IOUT [mA]

3.3

3.4

3.2

= 5.5 V

= 3.7 V

2. 4 VOUT = 4.0 V (RFB1 = 51 kΩ, RFB2 = 9 kΩ)

(1) Output current (IOUT) vs. Efficiency (η) (2) Output current (IOUT) vs. Output voltage (VOUT)

0 1000

η [%]

100

1 10 100

IOUT [mA]

90 V

= 4.4 V

= 5.5 V

0 1000

OUT

[V]

4.2

3.8

1 10 100

IOUT [mA]

4.0

4.1

3.9

= 5.5 V

= 4.4 V

3. Output current (IOUT) vs. Ripple voltage (Vr) Characteristics

3. 1 VOUT = 1.1 V (RFB1 = 36 kΩ, RFB2 = 43 kΩ)

(1) VIN = 3.6 V (2) VIN = 5.5 V

0 1000

Vr [mV]

1 10 100

OUT

[mA]

0 1000

Vr [mV]

1 10 100

OUT

[mA]

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

Rev.2.1_01 S-8550/8551 Series

Seiko Instruments Inc. 21

3. 2 VOUT = 1.8 V (RFB1 = 36 kΩ, RFB2 = 18 kΩ)

(1) VIN = 3.6 V (2) VIN = 5.5 V

0 1000

[mV]

1 10 100

IOUT [mA]

0 1000

[mV]

1 10 100

IOUT [mA]

3. 3 VOUT = 3.3 V (RFB1 = 36 kΩ, RFB2 = 8 kΩ)

(1) VIN = 3.6 V (2) VIN = 5.5 V

0 1000

Vr [mV]

1 10 100

OUT

[mA]

0 1000

Vr [mV]

1 10 100

OUT

[mA]

3. 4 VOUT = 4.0 V (RFB1 = 51 kΩ, RFB2 = 9 kΩ)

(1) VIN = 5.5 V

0 1000

[mV]

1 10 100

IOUT [mA]

STEP-DOWN

BUILT-IN FET

SYNCHRONOUS RECTIFICATION

PWM CONTROL SWITCHING REGULATORS

S-8550/8551 Series Rev.2.1_01

22 Seiko Instruments Inc.

 Marking Specification

(1) SOT-23-5

(1) to (3) : Product code (Refer to Product name vs. Product code.)

(4) : Lot number

5 4

1 3

(1) (2) (3) (4)

SOT-23-5

vie

Product name vs. Product code

(a) S-8550 Series (b) S-8551 Series

Product Code Product Code

Product Name (1) (2) (3) Product Name (1) (2) (3)

S-8550AA-M5T1G R 5 A S-8551AA-M5T1G R 5 C

No.

TITLE

SCALE

UNIT mm

Seiko Instruments Inc.

2.9±0.2

1.9±0.2

0.95±0.1

0.4±0.1

0.16 +0.1

-0.06

123

No. MP005-A-P-SD-1.2

MP005-A-P-SD-1.2

SOT235-A-PKG Dimensions

No.

TITLE

SCALE

UNIT mm

Seiko Instruments Inc.

ø1.5 +0.1

-0 2.0±0.05

ø1.0 +0.2

-0 4.0±0.1

1.4±0.2

0.25±0.1

3.2±0.2

123

No. MP005-A-C-SD-2.1

MP005-A-C-SD-2.1

SOT235-A-Carrier Tape

Feed direction

4.0±0.1(10 pitches:40.0±0.2)

No.

TITLE

SCALE

UNIT mm

Seiko Instruments Inc.

12.5max.

9.0±0.3

ø13±0.2

(60°) (60°)

QTY. 3,000

No. MP005-A-R-SD-1.1

MP005-A-R-SD-1.1

SOT235-A-Reel

Enlarged drawing in the central part

•

The information described herein is subject to change without notice.

• Seiko Instruments Inc. is not responsible for any problems caused by circuits or diagrams described herein

whose related industrial properties, patents, or other rights belong to third parties. The application circuit

examples explain typical applications of the products, and do not guarantee the success of any specific

mass-production design.

• When the products described herein are regulated products subject to the Wassenaar Arrangement or other

agreements, they may not be exported without authorization from the appropriate governmental authority.

• Use of the information described herein for other purposes and/or reproduction or copying without the

express permission of Seiko Instruments Inc. is strictly prohibited.

• The products described herein cannot be used as part of any device or equipment affecting the human

body, such as exercise equipment, medical equipment, security systems, gas equipment, or any apparatus

installed in airplanes and other vehicles, without prior written permission of Seiko Instruments Inc.

• Although Seiko Instruments Inc. exerts the greatest possible effort to ensure high quality and reliability, the

failure or malfunction of semiconductor products may occur. The user of these products should therefore

give thorough consideration to safety design, including redundancy, fire-prevention measures, and

malfunction prevention, to prevent any accidents, fires, or community damage that may ensue.