SSC SS6550

SS6550
Low-Noise Synchronous PWM Step-Down DC/DC Converter
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Greater than 95% efficiency.
Guaranteed output current of 800mA.
100% duty cycle in dropout.
Fixed 500 KHz or adjustable frequency sychronous PWM operation.
Very low quiescent current of 35µA (typ.).
Adjustable output voltage from 0.75V to VIN,
ranging from 2.5V to 5.5V.
Accurate reference: 0.75V (±1.2%).
Synchronizable external switching frequency
up to 1MHz.
Small 8-Pin MSOP package.
APPLICATIONS
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FEATURES
PDAs.
Handy-terminals.
WLAN cards
Cellular phones.
CPU I/O supplies.
Cordless phones.
Notebook chipset supplies.
Battery-operated devices (3 or 1 Li-Ion/NiMH/
NiCd Cells).
TYPICAL APPLICATION CIRCUIT
VIN= 2.5V to 5.5V
1
2
BP
+
CIN
10µF
VIN
BP
3
4
CBP
0.1µF
SHDN
LX
DESCRIPTION
The SS6550 is a low-noise pulse-widthmodulated (PWM) DC/DC step-down converter,
which can power logic circuits and transmitters in
small wireless systems such as communicating
PDAs, cellular phones and handy-terminals.
The device features an internal synchronous rectifier for high conversion efficiency. Excellent
noise characteristics and fixed-frequency operation provide easy post-filtering. The SS6550
is ideally suited for Li-Ion battery applications. It
is also suitable for +3V or +5V fixed input applications. The device operates in one of the following four modes. Forced PWM mode operates at a
fixed frequency regardless of the load. Synchronizable PWM mode allows the synchronization of
an external switching frequency and minimizes
harmonics. PWM/PFM Mode extends battery life
by switching to a PFM pulse-skipping mode under light loads. Shutdown mode places the device in standby, reducing supply current to under
0.1µA.
The SS6550 can deliver over 800mA of output current. The output voltage can be adjusted
from 0.75V to VIN with the input range of +2.5V
to +5.5V. Other features of the SS6550 include
low quiescent current, low dropout voltage, and a
±1.2% accuracy 0.75V reference. It is available in a space-saving 8-pin MSOP package.
GND 7
*
10µF
SYNC/ 6
MODE
1N5819
RT
Optional
FB
5
VOUT = 1.8V
L1
8
R1
560K
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15P
+
SS6550
R2
400K
Rev.2.01 6/06/2003
CF
CO1
33µF
CO2
4.7µF
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SS6550
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ORDERING INFORMATION
PIN CONFIGURATION
SS6550CXXX
PACKING TYPE
TR: TAPE & REEL
TB: TUBE
PACKAGE TYPE
O: MSOP8
TOP VIEW
VIN
1
8
BP
2
7 GND
SHDN 3
FB
4
LX
6 SYNC/MODE
5 RT
Example: SS6550COTR
à in MSOP package in tape & reel
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ABSOLUTE MAXIMUM RATINGS
VIN, BP, SHDN, SYNC/MODE, RT to GND
-0.3 to +6V
.-0.3 to 0.3V
BP to VIN
LX to GND
-0.3 to (VIN+0.3V)
FB to GND
-0.3 to (VBP+0.3V)
Operating Temperature Range
-40°C ~ 85°C
Storage Temperature Range
Rev.2.01 6/06/2003
- 40°C ~ 150°C
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ELECTRICAL CHARACTERISTICS (VIN=+3.6V, TA=+25°C, SYNC/MODE =GND,
SHDN =IN, unless otherwise specified.)
PARAMETER
Input Voltage Range
SYMBOL CONDITIONS
VIN
Output Adjustment Range
VOUT
Feedback Voltage
VFB
(Note 1)
Load Regulation
P-channel On-Resistance
IFB
Threshold
50
nA
VIN = 3.6V
0.32
0.65
VIN = 2.5V
0.38
Ω
VIN = 3.6V
0.32
0.65
VIN = 2.5V
0.38
Ω
1.2
1.55
A
35
70
µA
0.1
1
µA
-20
0.1
20
µA
400
500
600
KHz
1000
KHz
0.85
SYNC/MODE = GND,
VFB = 1.4V, LX unconnected
SHDN = LX = GND, includes LX
leakage current
VIN = 5.5V, VLX = 0 or 5.5V
f OSC
500
dutyMAX
UVLO
100
VIN rising, typical hysteresis is
85mV
SHDN , SYNC/MODE, LIM
Logic Input Low
VIL
SHDN , SYNC/MODE, LIM
Pulse Width
Note 1:
Rev.2.01 6/06/2003
V
0.75
0.01
VIH
SYNC/MODE Minimum
0.765
-50
Logic Input High
Logic Input Current
V
%/A
SYNC Capture Range
Undervoltage Lockout
VIN
-1.3
Threshold
Maximum Duty Cycle
VREF
IOUT = 0 to 800mA
P-channel Current-Limit
Oscillator Frequency
5.5
%
N-channel On-Resistance NRDS(ON) ILX = 100mA
LX Leakage Current
UNITS
+1
PRDS(ON) ILX = 100mA
Shutdown Supply Current
MAX
Duty Cycle = 100% to 23%
VFB = 1.4V,
Quiescent Current
TYP
2.5
0.735
Line Regulation
FB Input Current
MIN
SHDN , SYNC/MODE, LIM
High or low
2.0
%
2.2
2.4
2
-1
500
V
V
0.1
0.4
V
1
µA
ns
Specifications to -40°C are guaranteed by design, not production tested.
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TYPICAL PERFORMANCE CHARACTERISTICS
(TA=25oC, VIN=3.6V, SYNC/MODE=GND, L = Coilcraft DS1608C-103, unless otherwise noted.)
90
100
VOUT=0.9
95
(%)
75
70
65
VIN=2.7V
90
VIN=2.7V
Efficiency
(%)
80
Efficiency
85
VIN=4.2V
VIN=3.6V
VIN=3.3V
85
80
75
70
VIN=4.2V
VIN=3.3V
VIN=3.6V
65
VOUT=1.5V
60
10
100
60
1000
10
Load Current (mA)
Fig. 1 Load Current vs. Efficiency (VOUT=0.9V)
Fig. 2
100
90
90
(%)
95
85
Efficiency
(%)
Efficiency
95
80
VIN=4.2V
75
VIN=3.6V
VIN=3.3V
VIN=3.3V
85
80
75
VIN=3.6V
VOUT=2.5V
65
VOUT=1.8V
60
60
10
100
1000
10
Load Current (mA)
Fig. 3
Load Current vs. Efficiency (VOUT=1.8V)
Fig. 4
100
95
95
90
90
(%)
100
85
80
Efficiency
(%)
VIN=4.2V
70
65
Efficiency
10
100
VIN=2.7V
70
100
Load Current (mA)
Load Current vs. Efficiency (VOUT=2.7V)
VIN=4.2V
75
VIN=3.6V
70
100
1000
Load Current (mA)
Load Current vs. Efficiency (VOUT=2.5V)
VIN=3.6V
85
80
VIN=4.2V
75
70
VOUT=3.0V
65
65
60
VOUT=3.3V
60
10
100
1000
200
Load Current (mA)
Fig. 5 Load Current vs. Efficiency (VOUT=3.0V)
Rev.2.01 6/06/2003
Fig. 6
400
600
800
1000
Load Current (mA)
Load Current vs. Efficiency (VOUT=3.3V)
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TYPICAL PERFORMANCE CHARACTERISTICS (continued)
100
0.765
0.760
Reference Voltage (V)
W/ Schottky Diode
Efficiency (%)
90
80
VIN=3.6V
VOUT=1.8V
70
W/O Schottky Diode
VIN=3.6V
0.755
0.750
0.745
0.740
0.735
0.730
60
10
100
0.725
-50
1000
-25
Load Current (mA)
Fig. 7 Load Current vs. Efficiency
(W/ or W/O Schottky Diode)
Fig. 8
550
540
25
50
75
100
125
Temperature (°C)
Reference Voltage vs. Temperature
550
540
VIN=3.6V
530
530
520
Frequency (KHz)
Frequency (KHz)
0
510
500
490
480
520
510
500
490
480
470
470
460
460
450
-40
-20
0
20
40
60
80
100
450
120
2.0
2.5
3.0
Temperature (°C)
Fig. 9
Oscillator Frequency vs. Temperature
Fig. 10
3.5
4.0
4.5
5.0
5.5
6.0
Supply Voltage (V)
Frequency vs. Input Voltage
1.82
0.44
0.42
Output Voltage (V)
RDSON (mΩ)
1.80
Main Switch
0.40
0.38
0.36
0.34
0.32
VIN=3.6V
1.78
1.76
0.30
0.28
1.74
Synchronous Switch
0.26
2.0
2.5
3.0
3.5
4.0
4.5
5.0
Supply Voltage (V)
Fig. 11
Rev.2.01 6/06/2003
RDSON vs. Supply Voltage
5.5
6.0
1.72
1
10
Fig. 12
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100
1000
Load Current (mA)
Output Voltage vs. Load Current
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TYPICAL PERFORMANCE CHARACTERISTICS (continued)
40.0
4.0
VOUT=3.3V
37.5
No Load Current (µA)
Supply Current (mA)
3.5
3.0
VOUT=2.5V
2.5
2.0
1.5
VOUT=1.8V
1.0
35.0
32.5
30.0
27.5
VOUT=1.8V
SYNC/PWM=GND
R1=560K R2=400K
25.0
0.5
22.5
SYNC/PWM=IN
0.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
Supply Voltage (V)
Fig. 13
Supply Current vs. Supply Voltage
20.0
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
Fig. 14
Supply Voltage (V)
No Load Current vs. Supply Voltage
Fig. 16
Start-up from Shutdown, RLOAD=3Ω
6.0
Operation Frequency (KHz)
1000
900
800
700
600
500
0
1000
Tuning Resistor (Ω)
Fig. 15
Operation Frequency vs. Tuning Resistor
VOUT=1.8V;
ILOAD=50mA to 500mA;
SYNC/MODE=GND
VOUT=1.8V;
I LOAD=50mA to 500mA;
SYNC/MODE=IN
Fig. 17 Load Transient Response
Rev.2.01 6/06/2003
Fig. 18
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Load Transient Response
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TYPICAL PERFORMANCE CHARACTERISTICS (continued)
VIN=3.3V to 5V,
IOUT=1.8V;
ILOAD=200mA to 500mA;
SYNC/MODE=IN
Fig. 19
Line Transient Response
Fig. 20 Short Circuit Protection
VIN=3.6V; VOUT=1.8V;
ILOAD=500mA to 500mA;
SYNC/MODE=IN
Fig. 21
Rev.2.01 6/06/2003
Switching Waveform
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SS6550
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BLOCK DIAGRAM
BP
Chip Supply
0.75V
REF
Current AMP .
SHDN
10
VIN
VIN
+
X5
5
S lope
RT
500KHz
O scillator
Q1
x1
C urrent Limit
Comparator
Compensation
Q1
X20
Frequency
SYNC
+
Selection
REF
PWM
Comparator
P hase
Compensation
FB
FB
REF
+
Error
AMP .
LX
A ntiShootThrough
Control Logic
+
Q3
PWM/PFM
Control
Zero Cross
Comparator
REF
n
+
+
GND
PFM
Comparator
PIN DESCRIPTIONS
PIN 1: VIN-
Supply voltage input. Input range
from +2.5V to +5.5V. Bypass with a
10µF capacitor.
PIN 2: BPSupply bypass pin, internally connected to VIN. Bypass with a 0.1µF
capacitor. Do not connect to an external power source other than VIN.
PIN 3: SHDN - Active-low, shutdown-control input.
Reduces supply current to 0.1µA in
shutdown.
PIN 4: FBFeedback input.
PIN 5: RTFrequency adjustable pin. Connect a
resistor from this pin to GND to decrease the frequency.
Rev.2.01 6/06/2003
PIN 6: SYNC/MODE- Oscillator sync and low-noise,
mode-control Input.
SYNC/MODE = VIN (Forced PWM
mode)
SYNC/MODE = GND (PWM/PFM
mode)
An external clock signal connected
to this pin allows for LX switching
synchronization.
PIN 7: GND- Ground.
PIN 8: LX-
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Inductor connection to the drains of
the internal power MOSFETs
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APPLICATION INFORMATION
through block. Similarly, when Q3 is on, Q2 will turn off.
Introduction
The SS6550 is a low-noise, pulse-width-modulated
(PWM), DC/DC step-down converter. It features an internal synchronous rectifier, which eliminates the external Schottky diode. The SS6550 is suitable for
Li-lon battery applications, or can be used with 3V or
5V fixed input voltages. It operates in one of the following four modes
The SS6550 provides a current limit function by using a 5Ω resistor. When Q1 turns on, current flows
through the 5Ω resistor and the current amplifier
senses the voltage across the resistor and amplifies it.
When the sensed voltage gets bigger than the reference voltage, the control logic shuts the device off.
PWM/PFM Function
1. The SS6550 can operate in PWM mode
with a fixed frequency, regardless of its
load.
2. In synchronizable PWM mode, it allows an
external switching frequency to control and
minimize harmonics.
3. In idle mode (PWM/PFM), it can extend
battery life by switching to PFM pulseskipping mode during light loads.
4. In shutdown mode, the device will stop
working and the supply current will reduce
to 0.1µA or less.
The continuous output current of the SS6550
can be up to 800mA and the output voltage can be
adjusted from 0.75V to VIN with an input range
from 2.5V to 5.5V using a voltage divider. The
SS6550 also features high efficiency, low dropout voltage, and a 0.75V reference with ±1.2% accuracy. It is available in a space-saving 8-pin
MSOP package.
When connecting the SYNC/MODE pin to VIN, the device is forced into the PWM (Pulse-Width-Modulated)
mode with constant frequency. The advantage of constant frequency is that noise can be reduced easily
without complex post-filtering. However, it has the disadvantage of low efficiency at light loading. Therefore,
the SS6550 provides a function to solve this problem. When connecting the SYNC/MODE pin to GND,
the device is able to get into PWM/PFM (PulseFrequency-Modulated) modes. Under a light load condition, the device shifts to PFM mode, which results in
a higher efficiency. PWM mode is on under heavy
loading and the noise is reduced.
Frequency Synchronization
Connecting an external clock signal to the
SNYC/MODE pin can control the switching frequency.
The acceptable range is from 500 kHz to 1 MHz. This
mode exhibits low output ripple as well as low audio
noise and reduces RF interference, while providing
reasonable low current efficiency.
Adjustable Switching Frequency
Operation
When powered on, the control logic block detects
whether the SYNC/MODE pin is connected to VIN or
GND to determine the operation function and gives a
signal to the PWM/PFM control block to determine the
proper comparator (ref. Block Diagram). The
SS6550 works with an internal synchronous rectifier
Q3, to increase efficiency. When the control logic block
turns Q2 on, Q3 will turn off through the anti-shortRev.2.01 6/06/2003
The decrease of the switching frequency can also be
controlled by connecting an external resistor from the
RT pin to ground (ref. Fig. 15). In this mode, the PFM
mode is disabled and the device operates with the adjusted frequency. This function is helpful in reducing
high frequency harmonics and a post-filter can be easily designed for this function. However, there will be an
increase in ripple voltage.
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SS6550
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APPLICATION INFORMATION (cont.)
100% Duty Cycle Operation
External Schottky Diode
When the input voltage approaches the output voltage,
the converter continuously turns Q1 on. In this mode,
the output voltage is equal to the input voltage minus
the voltage-drop across Q1.
The SS6550 has an internal synchronous rectifier,
instead of the Schottky diode usually found in a buck
converter. However, a blank period occurs at each
switching cycle when both the main switch, Q2, and the
synchronous rectifier, Q3, are off. This results in a decrease in efficiency. Therefore, an external Schottky
diode is needed to reinforce the efficiency.
Components Selection
Inductor
The inductor selection depends on the operating frequency of the SS6550. The internal switching frequency is 500 kHz, and the external synchronized frequency ranges from 500 kHz to 1 MHz. A higher frequency allows the use of smaller inductor and capacitor
values. However, higher frequency also results in lower
efficiency due to the internal switching loss.
The ripple current ∆ IL is related to the inductor value. A
lower inductor value creates a higher ripple current. A
higher VIN or VOUT can also create the same result. The
inductor value can be calculated from the following formula:
 VOUT 
1
1 −

V
=
...(1)
(f )(∆IL ) OUT  VIN 
Users can define the acceptable ripple current to
obtain a suitable inductor value.
Output Capacitor
The selection of output capacitor depends on the acceptable ripple voltage. Lower ripple voltage corresponds to lower ESR (equivalent-series-resistance) of
the output capacitor. Typically, once the ESR is determined from the ripple voltage, the value of the capacitor is adequate for filtering. The formula for ripple voltage is:

1 

∆VOUT = ∆IL  ESR +

8
fC
OUT 

Since the diode conducts during the off time, the peak
current and voltage of the converter must not exceed
the diode ratings. The ratings of the diode can be calculated from the following formulae:
VD,MAX (OFF ) = VIN
∆IL
2
− D × IOUT
ID,MAX( ON) = IOUT,MAX +
ID,avg ( ON) = IOUT − IIN = IOUT
= (1 − D) × IOUT
Adjustable Output Voltage
The SS6550 presents a 0.75V reference voltage at
the FB pin. The output voltage, ranging from 0.75V to
VIN, can be set by connecting two external resistors, R1
and R2. VOUT can be calculated as:
R1
VOUT = 0.75 V × (1 +
)
R2
Applying a 15µF capacitor in parallel with R1 can prevent stray pickup. This should sit as close to the
SS6550 as possible. However, the load transient
response is degraded by this capacitor.
For more reduction in the ripple voltage, a 15pF ceramic capacitor can be used in parallel with the output
capacitor.
Rev.2.01 6/06/2003
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APPLICATION INFORMATION (cont.)
L=
Layout Consideration
To ensure proper operation of the SS6550, the following
points should be considered:
1. The input capacitor and VIN should be placed as
close as possible to each other to avoid the AC
current flow into the internal MOSFET.
2. The output loop, which consists of the inductor,
Schottky diode and output capacitor, should be
kept as small as possible.
3. The routes carrying large currents should be
kept short and wide.
4. Logically the large current of the converter,
when SS6550 is on or off, should flow in the
same direction.
5. The FB pin should connect to the feedback resistors directly, and the route should be away
from any noise source, such as the inductance
of the LX line.
6. Grounding all components at the same point
may effectively reduce the occurrence of loops.
A stable ground plane is very important to obtain
higher efficiency. When a ground plane is cut
apart, it may cause disturbed signals and noise.
If possible, two or three through-holes can ensure the stability of grounding. Fig.2 to 4 shows
1.8 V
 1 .8 V 
1 −
 = 8.23µH
500kHz × 250mA 
4.2V 
Therefore, 10µH is appropriate for the inductor. The inductor, series number SLF6025-100M1R0 from TDK,
with 57.3mΩ series resistance is recommended for the
best efficiency.
For the output capacitor, the ESR is more important
than its capacitance. Assuming ripple voltage
o f 100mV, then the ESR can be calculated as:
∆V 100mV
ESR=
=
= 0.4Ω
∆I 250mA
Therefore, a 33µF/10V capacitor, MCM series from
NIPPON, is recommended.
Schottky selection is calculated as following.
VD,MAX ( OFF ) = VIN = 4.2 V
∆IL
2
250mA
= 800mA +
2
ID,MAX(ON) = IOUT,MAX +
= 925mA
ID,avg( ON)
= (1 − D) × IOUT
1 .8
) × 800mA
4.2
= 457 .14mA
= (1 −
the layout diagrams of the SS6550.
Example
Here is an example to illustrate the components selection guide lines above. Let’s assume the SS6550 is
to be used for a mobile phone application, which uses a
1-cell Li-Ion battery with 2.7V to 4.2V input voltage for
the power source. The required load current is 800mA,
and the output voltage is 1.8V. Substituting VOUT=1.8V,
VIN=4.2V, ri p p l e =250mA, and f=500 kHz to equation (1)
Rev.2.01 6/06/2003
According to the data above, the Schottky diode, SS12,
from GS is recommended.
For feedback resistors, choose R2=390kΩ, and then
R1 can be calculated as follow:
 1.8 V

R1 = 
− 1 × 390kΩ = 546kΩ ; use 560kΩ
0
.
75


Fig. 22 shows this application circuit for the SS6550.
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APPLICATION INFORMATION (cont.)
VIN
2.7V~5.5V
1
+ C1
10µF
C2
0.1µF
2
3
SW1
4
VIN
BP
LX
GND
SHDN
L1
8
6
SW
SYNC
FB
RT
SS6550
VOUT
10µH
7
5
D1
SS12
Optional
C5
15pF
R1
C4
560K 33µF
+
C3
4.7µF
RT
R2
390K
Fig. 22 SS6550 Application Circuit
Rev.2.01 6/06/2003
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PHYSICAL DIMENSIONS
l
MSOP 8 (unit: mm)
D
SYMBOL
MIN
MAX
A
0.76
0.97
A1
--
0.20
B
0.28
0.38
C
0.13
0.23
D
2.90
3.10
E
2.90
3.10
H
E
e
e
A
A1
C
B
0.65
H
4.80
5.00
L
0.40
0.66
L
Information furnished by Silicon Standard Corporation is believed to be accurate and reliable. However, Silicon Standard Corporation makes no
guarantee or warranty, express or implied, as to the reliability, accuracy, timeliness or completeness of such information and assumes no
responsibility for its use, or for infringement of any patent or other intellectual property rights of third parties that may result from its
use. Silicon Standard reserves the right to make changes as it deems necessary to any products described herein for any reason, including
without limitation enhancement in reliability, functionality or design. No license is granted, whether expressly or by implication, in relation to
the use of any products described herein or to the use of any information provided herein, under any patent or other intellectual property rights of
Silicon Standard Corporation or any third parties.
Rev.2.01 6/06/2003
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