SSC SS9175CS-10

SS9175/6
Dual Synchronous DC/DC Controllers With Current Sharing Circuitry
FEATURES
DESCRIPTION
Two sets of integrated MOSFET drivers
Fixed operating frequency of 300, 600 or 1000kHz
Dual-phase current-sharing controller to minimize
ripple and improve transient response
Wide input supply range: 4.5V to 16V
Programmable output as low as 0.8v
Internal error amplifier reference voltage of
0.7V +/- 1%
Programmable over-current protection (OCP) with
50% fold-back
Over-voltage protection (OVP)
Soft-start
Remote ON/OFF control
High voltage pin up to 30V for bootstrap voltage
Power-good output signal provided
Current-sharing balance within +/-5% matching
(SS9175CS/SS9176CS)
Two independent PWM controllers (SS9175)
Packaged in SO-20 (9175/CS) or SO-16 (9176CS)
The SS9175 is a 20-pin version that is designed for
two independent outputs without current sharing
capability.
APPLICATIONS
n
n
n
n
The SS9175/6 series are dual-phase synchronous
DC/ DC PW M cont rol l ers f or power s u p p l i e s
requiring a single high-current output, or two
independent outputs with high conversion efficiency.
They integrate two sets of internal MOSFET drivers
consisting of high-side and low side driving circuits.
The internal temperature-independent reference
voltage is trimmed to 0.7V +/- 1%, and is connected to
the error amplifier’s positive terminal for voltage
feedback regulation. The over-current protection
(OCP) level, with 50% fold-back, can be programmed
by an external resistor. The over-voltage protection
(OVP) point is fixed at 25% higher above 0.7V. The
soft-start circuit ensures the duty cycle of the PWM
output can be gradually and smoothly increased from
zero to its desired value. The controllers can be
remotely turned ON or OFF to enter into either active
or standby mode, respectively. The SS9175/6
series provides three different options:
CPU and DSP Vcore Power Supply
Graphic cards
Telecomm and datacomm POL boards
Power supplies requiring two independent outputs
The SS9175CS is a 20-pin version designed for
current sharing applications.
The SS9176CS is a 16-pin version for current
sharing applications.
TYPICAL APPLICATION CIRCUIT
PWRG
1.4v
5V
12V
2.2pF
1uF
7.5uH
1k
PWRG
IN1
COM
VCC
CL1+
CL1BST1
DH1
DL1
PGND
GND
IN2
COM
SS/ENB
CL2+
CL2BST2
DH2
DL2
BSTC
1k
1uF
7.5uH
50k
10uF
450uF
50k
0.22uF
Rev.2.02 12/29/2003
PRELIMINARY
www.SiliconStandard.com
1 of 12
SS9175/6
ORDERING INFORMATION
SS917x xx-xx xx
Packing:
TR tape and reel: TB tubes
Fixed operating frequency:
3/6/10 for 300/600/1000kHz
Configuration:
CS = current sharing; blank = independent outputs (9175 only)
Part/package type:
9175 is in SO-20; 9176 is in SO-16
Examples: SS9176CS-10TR
SS9176 with current-sharing outputs, 1000kHz in SO-16 on tape and reel
SS9175-6TR
SS9175 with independent outputs, 600kHz in SO-20 on tape and reel
MARKING INFORMATION
16
20
SS9175UU-H
SS9176CS-H
XXXXXXXYYWWV
XXXXXXXYYWWV
1
1
UU:
= SS9175
UU: CS = SS9175CS
H : 3, 6 or 10
XXXXXXX: Wafer Lot
YY: Year; WW: Week
V: Assembly Location
Rev.2.02 12/29/2003
PRELIMINARY
H : 3, 6 or 10
XXXXXXX: Wafer Lot
YY: Year; WW: Week
V: Assembly Location
www.SiliconStandard.com
2 of 12
SS9175/6
ABSOLUTE MAXIMUM RATINGS
Symbol
Vcc
PGND
VBST
RT j-a
TJ
TA
Tstg
Parameter
Test Condition
Supply voltage, VCC to GND
PGND to GND
BST to PGND
Thermal resistance, Junction-air
Operating junction temperature
Operating ambient temperature
Storage temperature range
ESD Capability, HBM model
ESD Capability, Machine model
Low impedance source
-
Value
Unit
20
± 0.7
30
90
-40 to +125
-30 to +85
-65 to +150
2.0
200
V
V
V
°C/W
°C
°C
°C
kV
V
RECOMMENDED OPERATING CONDITIONS
Symbol
VCC
TA
Parameter
Min.
Max.
Unit
4.5
0
16
70
V
°C
Supply voltage
Operating ambient temperature
ELECTRICAL CHARACTERISTICS (VCC=12V, Ta=25°C)
Oscillator Section
Symbol
Parameter
Test Condition
Fosc-3
Fosc-6
Fosc-10
fdv
fdt
DC Max
Oscillator frequency -3 version
Oscillator frequency -6 version
Oscillator frequency -10 version
Frequency change with VCC
Frequency change with temp.
Maximum duty cycle
Ta=25°C
Ta=25°C
Ta=25°C
VCC=4.5 to 16V
Ta=0 to 70°C
Min.
Typ.
Max.
Unit
270
550
920
85
300
600
1000
0.2
0.02
95
330
650
1080
KHz
KHz
KHz
%
%/°C
%
-
Error Amplifier Section
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
Vref
Avol
BW
PSRR
Isource
Isink
VH COMP
VL COMP
Internal reference voltage
Open-loop voltage gain
Unity gain bandwidth
Power supply rejection ratio
Output source current
Output sink current
Output voltage
Output voltage
Ta=25°C
-
0.693
45
0.7
50
0.7
55
1.2
-
0.707
-
V
dB
MHz
dB
mA
mA
V
mV
Output Section
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
Tr
Tf
IDH, CH
IDH, DIS
Rising time
Falling time
High side source current
High side sink current
Ta=25°C, CL=10nF
Ta=25°C, CL=10nF
1
1
20
20
50
50
nS
nS
A
A
Min.
Typ.
Max.
Unit
-
5.0
mA
0.5
mA
Total Operating Current Section
Symbol
Parameter
Test Condition
ICC OP
Operating supply current
VCC=12V, OUTPUT=1000pF
ICC SBY
Standby current (disabled)
Rev.2.02 12/29/2003
PRELIMINARY
www.SiliconStandard.com
3 of 12
SS9175/6
BLOCK DIAGRAMS
SS9175
VCC
LDO
VDD
POR
LDO
C
BSTC
BST1
Q
D
CL1+
R
DH1
COMP1
OCP
IN1
CL1DL1
OSC
PWRGD
BG
PWRGD
BST2
OSC
CL2+
DH2
OSC180
IN2
OCP
COMP2
DL2
Q
D
GND
CL2-
C
GND
R
PGND
25u
SS/ENB
SS9175CS
VCC
LDO
VDD
POR
LDO
D
C
BSTC
BST1
Q
CL1+
R
DH1
COMP1
CS
IN1
OCP
CL1 DL1
OSC
PWRGD
BG
PWRGD
BST2
OSC
CL2+
DH2
OSC180
CS
OCP
CL2DL2
Q
D
GND
C
GND
R
PGND
25u
SS/ENB
Rev.2.02 12/29/2003
PRELIMINARY
www.SiliconStandard.com
4 of 12
SS9175/6
BLOCK DIAGRAMS (cont.)
SS9176CS
VCC
LDO
VDD
POR
LDO
C
COMP
BSTC
BST1
Q
D
CL+
R
DH1
CS
IN
OCP
CL1 DL1
OSC
BG
BST1
OSC
PWRGD
PWRGD
DH2
OSC180
CS
OCP
CL2DL2
GND
GND
D
C
25u
Q
R
PGND
SS/ENB
Rev.2.02 12/29/2003
PRELIMINARY
www.SiliconStandard.com
5 of 12
SS9175/6
PIN DESCRIPTIONS
Pin No.
Symbol
Description
Function
Output of the error amplifier and input to the PWM comparator. It is used for feedback
loop compensation.
Inverting input of the error amplifier. It is normally connected to the switching power
supply output through a resistor divider.
1 (1)
PWRGD
Power-good
2 (2)
IN1
Feedback
3 (3)
COMP1
Compensation
4 (4)
VCC
Power Supply
5
CL1+
Over-current
6
7 (5)
8 (6)
9 (7)
10 (8)
CL1BST1
DH1
DL1
PGND
Over-current
Boost supply
High-side drive
Low-side drive
Driver ground
11 (9)
BSTC
Buffered supply
12 (10)
13 (11)
14 (12)
15 (13)
DL2
DH2
BST2
CL2-
Low-side drive
High-side drive
Boost supply
Over-current
16 (14)
CL2+
Over-current
17 (15)
SS/EN
Soft-start/Enable
18
COMP2
[NC]
Compensation
19
IN2 [NC]
Feedback
20 (16)
GND
Control ground
Output of the error amplifier and input to the PWM comparator. It is used for feedback
loop compensation.
Supply voltage input.
Over-current adjustment and high-side MOSFET supply voltage sense pin. Connect
a resistor from this pin to high-side supply voltage.
Over-current sense pin.
Supply for high-side driver. Connect to bootstrap circuit.
High-side MOSFET gate driver pin.
Low-side MOSFET gate driver pin.
Driver circuit GND supply. Connect to MOSFET’s GND.
Voltage supply for internal low-side driver circuit and for high-side bootstrap circuit’s
diode input. Its output is 6V if chip supply voltage VCC > 6.5V. If VCC < 6.5V, then BSTC
= VCC. Need a 10uF decoupling capacitor connected to PGND.
Low-side MOSFET gate driver pin.
High-side MOSFET gate driver pin.
Supply for high-side driver. Connect to bootstrap circuit.
Over-current sense pin.
Over-current adjustment and high-side MOSFET supply voltage sense pin. Connect a
resistor from this pin to high-side supply voltage.
A 25uA internal current source charges an external capacitor for soft start. Pull down this
pin to disable the chip.
Output of the error amplifier and input to the PWM comparator. It is used for feedback
loop compensation.
Inverting input of the error amplifier. It is normally connected to the switching power
supply output through a resistor divider.
Control circuit GND supply.
Note: Inside ( ) is the pin assignment for SS9176CS. Inside [ ] is for SS9175CS.
PIN CONFIGURATIONS
SS9175
SS9176
PWRGD
1
20
GND
IN1
2
19
IN2
PWRGD
1
16
GND
IN
2
15
SS/ENB
COMP1
3
18
COMP2
VCC
4
17
SS/ENB
COMP
3
14
CL+
CL1
5
16
CL2+
VCC
4
13
CL2-
CL1+
6
15
CL2-
BST1
5
12
BST2
BST1
7
14
BST2
DH1
6
11
DH2
DH1
8
13
DH2
DL1
7
10
DL2
PGND
8
9
BSTC
DL1
PGND
Rev.2.02 12/29/2003
9
10
PRELIMINARY
12
11
DL2
BSTC
www.SiliconStandard.com
6 of 12
SS9175/6
APPLICATION INFORMATION
OPERATION
Over-current protection
The SS9175/6 series controllers integrate two sets
of synchronous MOSFET driver circuits with current
sharing capability. The following descriptions highlight
the advantages of the SS917x designs.
Soft-start
A 25uA start-up current is provided by the SS/EN pin
for the start-up sequence. During this start-up
sequence, the SS917x is disabled when the SS/EN
pin is less than 1.0V. From 1.0V to 3.0V, PWM output
duty cycle is gradually and smoothly increased to its
desired value. During this time, the current sharing
circuit is disabled for smooth soft start. After 3.0V, the
current sharing circuit is enabled and the whole circuit
operates normally.
Oscillator operation
The SS9175/6 series have three versions with
different oscillation frequencies. The oscillation
frequency is fixed at 300 kHz, 600 kHz or 1 MHz. The
voltage amplitude of the internal saw tooth oscillator is
from 1.2V to 2.8V.
The over-current protection (OCP) is implemented by
adding a resistor from the MOSFET supply voltage to
the CL+ pin, which sinks a 100uA current source. An
internal comparator senses the voltage difference
between CL+ and CL- pin. If the CL- pin voltage is
lower than the CL+ pin voltage, meaning there is a
larger current flowing through the high-side MOSFET,
the comparator will trigger the OCP protection. The
OCP function also has a 50% fold-back circuit to limit
the MOSFET current within the desired over-current
value.
Output driver
The high-side driver uses an external bootstrap circuit
to provide the required boost supply voltage. The
external bootstrap circuit uses the BSTC output
voltage for providing the diode voltage. For the
low-side driver, the supply voltage is coming from the
BSTC output voltage, which is roughly 6V if VCC is
larger than 6.5V.The output stage is designed to
ensure zero cross-conduction current.
Error amplifier
The error amplifier’s inverting input is connected to the
IN pin, and the output is connected to the COMP pin.
The COMP output is available for external
compensation, allowing designers to control the
feedback-loop frequency-response. Non-inverting
input is not wired out to a pin, but it is internally biased
to a fixed 0.7V ± 1% voltage.
Rev.2.02 12/29/2003
PRELIMINARY
Current Sharing
The dual-phase controller has current-sharing
capability to match both channels to within 5%.
www.SiliconStandard.com
7 of 12
SS9175/6
APPLICATION INFORMATION (cont.)
REFERENCE CIRCUITS
Current sharing application using SS9176CS
PWRG
1.4v
12v
1uF
7.5uH
2.2pF
PWRGD GND
IN1 SS/ENB
COMP CL2+
VCC
CL2BST1 BST2
DH1
DH2
DL1
DL2
PGND BSTC
1k
1uF
7.5uH
50k
450uF
10uF
50k
0.22uF
This current sharing circuit is implemented using
the SS9176CS. The dual phase MOSFETs
must be supplied from the same supply voltage (in
this case, from 12V). They can also be supplied from
a 5V supply voltage. As there is only a single output
voltage (1.4V in this case), the divided voltage is
fed back to the IN pin. The VCC supply voltage can
be either 12V or 5V, depending on the
Rev.2.02 12/29/2003
PRELIMINARY
convenience of PCB layout, but VCC = 12V is
recommended. If VCC > 6.5V, the BSTC output is
fixed at 6V. This BSTC voltage is used as the
supply voltage for the bootstrap circuit’s diodes
input. A 10uF capacitor is recommended for BSTC
decoupling. A 1k resistor is connected from CL2+
to the MOSFET’s high-side voltage. This 1k
resistor is used to program the OCP level.
www.SiliconStandard.com
8 of 12
SS9175/6
APPLICATION INFORMATION (cont.)
Current sharing application using SS9175CS
PWRG
1.4v
5V
12V
2.2pF
1uF
7.5uH
1k
PWRGD
IN1
COMP1
VCC
CL1+
CL1BST1
DH1
DL1
PGND
GND
IN2
COMP2
SS/ENB
CL2+
CL2BST2
DH2
DL2
BSTC
1k
1uF
7.5uH
10uF
450uF
50k
50k
0.22uF
This current-sharing circuit is implemented using
SS9175CS. The dual phase MOSFETs can be
supplied from different supply voltages (in this case,
from 12V for channel 2, and 5V for channel 1).
They can be supplied from the same supply
voltage, too. As there is only a single output
voltage (1.4V in this case), the divided voltage is
fed back to the IN1 pin. The VCC supply voltage
can be either 12V or 5V, depending on the
Rev.2.02 12/29/2003
PRELIMINARY
convenience of PCB layout, but VCC = 12V is
recommended. If VCC > 6.5V, the BSTC output is
fixed at 6V. This BSTC voltage is used as the
supply voltage for the bootstrap circuit’s diodes
input. A 10uF capacitor is recommended for BSTC
decoupling. A 1k resistor is connected from CL2+
to the MOSFET’s high-side voltage. This 1k
resistor is used to program the OCP level.
www.SiliconStandard.com
9 of 12
SS9175/6
n APPLICATION INFORMATION (cont.)
Two independent voltage outputs using SS9175
2.1v
PWRG
5V
12V
2.2pF
1uF
7.5uH
50k
450uF
1k
PWRGD
IN1
COMP1
VCC
CL1+
CL1BST1
DH1
DL1
PGND
GND 2.2pF
IN2
COMP2
SS/ENB
CL2+
CL2BST2
DH2
DL2
BSTC
1k
1uF
7.5uH
10uF
25k
450uF
50k
50k
0.22uF
For independent outputs, this design is implemented
using SS9175. The dual-phase MOSFETs can be
supplied from different supply voltages (in this case,
from 12V for channel 2, and 5V for channel 1).
They can be supplied from the same supply
voltage, too. As there are two independent output
voltages (2.1V and 1.4V in this case), the divided
voltages are fed back to their respective IN1 and
IN2 pins. The VCC supply voltage can be either
Rev.2.02 12/29/2003
PRELIMINARY
12V or 5V, depending on the convenience of PCB
layout, but VCC = 12V is recommended. If VCC >
6.5V, the BSTC output is fixed at 6V. This BSTC
voltage is used as the supply voltage for the
bootstrap circuit’s diodes input. A 10uF capacitor is
recommended for BSTC decoupling. A 1k resistor
is connected from CL1+ and CL2+ to the
MOSFET’s high-side voltages. This 1k resistor is
used to program the OCP level.
www.SiliconStandard.com
10 of 12
SS9175/6
PHYSICAL DIMENSIONS
20 LEAD SOP (unit: inches)
Dimensions:
Rev.2.02 12/29/2003
PRELIMINARY
www.SiliconStandard.com
11 of 12
SS9175/6
PHYSICAL DIMENSIONS (cont.)
16 LEAD SOP (units: inches)
Dimensions:
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.2.02 12/29/2003
PRELIMINARY
www.SiliconStandard.com
12 of 12