RT8108 - Richtek

RT8108
5V to 12V Single Synchronous Buck PWM Controller
General Description
Features
The RT8108 series are single-phase synchronous buck
PWM DC/DC controllers designed to drive two
N-MOSFETs. They provide a highly accurate,
programmable output voltage precisely regulated to low
voltage requirement with an internal 0.6V or 0.8V reference.
z
Single IC Supply Voltage ( 5V to 12V)
z
Drive Two N-MOSFETs
Fixed Operating Frequency at 200kHz, 300kHz and
500kHz
Voltage Mode PWM Control with External
Feedback Loop Compensation
Over Current Protection by Sensing MOSFET RDS(ON)
Hardware Pin for On/Off Control
Full 0 to 90% Duty Cycle
Fast Transient Response
RoHS Compliant and Halogen Free
The RT8108 series use a single feedback loop voltage mode
PWM control for fast transient response. The high driving
capability makes it suitable for large output current
applications. An oscillator with fixed frequency 200kHz /
300kHz / 500kHz reduces the component size of the
external inductor and capacitor for saving PCB board area
and cost.
The RT8108 series integrate complete protection functions
such as OCP, OVP and OTP UVP into SOP-8 and SOP-8
(Exposed Pad) surface mount packages.
Ordering Information
RT8108
Package Type
S : SOP-8
SP : SOP-8 (Exposed Pad-Option 1)
Lead Plating System
G : Green (Halogen Free and Pb Free)
Frequency / VREF Options
A : 300k / 0.6V
B : 300k / 0.8V
C : 200k / 0.6V
D : 200k / 0.8V
E : 500k / 0.6V
F : 500k / 0.8V
Note :
z
z
z
z
z
z
z
Applications
z
z
z
z
Mother Boards and Desktop Servers
Graphic Cards
Switching Power Supply
Generic DC/DC Power Regulator
Pin Configurations
(TOP VIEW)
8
PHASE
UGATE
2
7
COMP/SD
GND
3
6
FB
LGATE/OCSET
4
5
VCC
8
PHASE
BOOT
SOP-8
BOOT
UGATE
2
GND
3
LGATE/OCSET
4
GND
7
COMP/SD
6
FB
5
VCC
9
Richtek products are :
`
RoHS compliant and compatible with the current require-
SOP-8 (Exposed Pad)
ments of IPC/JEDEC J-STD-020.
`
Suitable for use in SnPb or Pb-free soldering processes.
DS8108-03
September 2011
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1
RT8108
Typical Application Circuit
VIN
3.3V to 12V
RT8108x
VCC
5V or 12V
5 VCC
CDCPL
7 COMP
/SD
RF
C1
EN
6
FB
BOOT 1
2
UGATE
8
PHASE
CHF
CBULK
RBOOT CBOOT
LOUT
RUGATE
VOUT
LGATE/ 4
OCSET
3
GND
R
COUT
C
CF
RS
ROFFSET
ROCSET
Functional Pin Description
Pin No.
Pin Nam e
SOP-8
SOP-8
(Exposed Pad)
1
1
BOOT
2
2
UGATE
Pin Function
Bootstrap Supply Pin for the Upper Gate Driver. Connect the
bootstrap capacitor between BOOT and PHASE pins.
Upper Gate Driver Output. Connect this pin to gate of the high side
power N-MOSFET.
Both Signal and Power Ground for the IC. Tie this pin directly to the
3
3,
9 (Exposed Pad)
GND
low-side MOSFET source and ground plane with the lowest
impedance. The exposed pad must be soldered to a large PCB
and connected to GND for maximum power dissipation.
Low-Side Gate Drive. It also acts as over current setup pin by
4
4
LGATE/OCSET
5
5
VCC
Connect this Pin to a Well-Decoupled 5V or 12V Bias Supply. It is
also the positive supply for the lower gate driver.
adjusting the resistor connecting to GND.
6
6
FB
Feedback of the Output Voltage.
7
7
COMP/SD
Feedback Compensation and Enable/Shutdown Control Pin.
8
8
PHASE
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2
Connect this pin to the source of the upper MOSFET and the drain
of the lower MOSFET.
DS8108-03
September 2011
RT8108
Function Block Diagram
VCC
Delay
5V
Sample
and Hold
+
OC
Comparator
IOCSET
PWM
Comparator
+
+
EA
0.2V
+
Internal
Regulator
-
INHIBIT
PWM
September 2011
UGATE
PHASE
Gate Control
Logic
DIS
VCC
DIS
LGATE/OCSET
Oscillator
Fixed 200kHz / 300kHz / 500kHz
DS8108-03
BOOT
5V int.
COMP/SD
DBOOT
-1
VREF
(0.6V / 0.8V)
FB
POR and
Soft-Start
-
GND
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RT8108
Absolute Maximum Ratings
z
z
z
z
z
z
z
z
z
z
z
z
z
(Note 1)
Supply Input Voltage, VCC ------------------------------------------------------------------------------ 16V
BOOT to PHASE ----------------------------------------------------------------------------------------- 15V
BOOT to GND
DC ------------------------------------------------------------------------------------------------------------ −0.3V to VCC + 15V
<200ns ------------------------------------------------------------------------------------------------------ −0.3V to 42V
PHASE to GND
DC ------------------------------------------------------------------------------------------------------------ −0.5V to 15V
<200ns ------------------------------------------------------------------------------------------------------ −5V to 30V
UGATE Voltage ------------------------------------------------------------------------------------------- VPHASE − 0.3V to VBOOT + 0.3V
<200ns ------------------------------------------------------------------------------------------------------ VPHASE − 5V to VBOOT + 5V
LGATE Voltage -------------------------------------------------------------------------------------------- GND − 0.3V to VCC + 0.3V
<200ns ------------------------------------------------------------------------------------------------------ GND− 5V to VCC + 5V
Other Input or Output Voltages ------------------------------------------------------------------------ GND − 0.3V to 7V
Power Dissipation, PD @ TA = 25°C
SOP-8 ------------------------------------------------------------------------------------------------------- 0.909W
SOP-8 (Exposed Pad) ---------------------------------------------------------------------------------- 1.333W
Package Thermal Resistance (Note 2)
SOP-8, θJA ------------------------------------------------------------------------------------------------- 110°C/W
SOP-8 (Exposed Pad), θJA ----------------------------------------------------------------------------- 75°C/W
SOP-8 (Exposed Pad), θJC ---------------------------------------------------------------------------- 28°C/W
Junction Temperature ------------------------------------------------------------------------------------ 150°C
Lead Temperature (Soldering, 10 sec.) -------------------------------------------------------------- 260°C
Storage Temperature Range --------------------------------------------------------------------------- −65°C to 150°C
ESD Susceptibility (Note 3)
HBM (Human Body Mode) ----------------------------------------------------------------------------- 2kV
MM (Machine Mode) ------------------------------------------------------------------------------------- 200V
Recommended Operating Conditions
z
z
z
(Note 4)
Supply Input Voltage, VCC ------------------------------------------------------------------------------ 5V ± 5%, 12V ± 10%
Junction Temperature Range --------------------------------------------------------------------------- −40°C to 125°C
Ambient Temperature Range --------------------------------------------------------------------------- −40°C to 85°C
Electrical Characteristics
(VCC = 12V, TA = 25°C, unless otherwise specified)
Parameter
Symbol
Test Conditions
Min
Typ
Max
Unit
4.75
--
13.2
V
Supply Input
Supply Input Voltage
V CC
Supply Current
ICC
UGATE, LGATE Open
--
2.5
10
mA
Shutdown Current
ISHDN
UGATE, LGATE Open
--
2
--
mA
POR Threshold
V CC_RTH
VCC Rising
3.8
4
4.3
V
Power On Reset Hysteresis
V CC_HYS
--
0.4
--
V
Power-On Reset
To be continued
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DS8108-03
September 2011
RT8108
Parameter
Symbol
Test Conditions
Min
Typ
Max
250
300
350
170
200
230
425
500
575
--
1.5
--
0.594
0.6
0.606
0.792
0.8
0.808
Unit
Oscillator
RT8108A/B
PWM
Frequency
RT8108C/D
F SW
RT8108E/F
ΔVOSC
Ramp Amplitude
kHz
VP-P
Reference
RT8108A/C/E
Reference
Voltage
RT8108B/D/F
V REF
V
PWM Controller
Open Loop DC Gain
AO
--
88
--
dB
Gain Bandwidth
GBW
--
15
--
MHz
Maximum Duty
DMAX
fOSC = 200kHz / 300kHz
--
92
--
%
fOSC = 500kHz
--
85
--
%
PWM Controller Gate Driver
Upper Gate Source
IUGATEsr
VBOOT − V PHASE = 12V
1
1.2
--
A
Upper Gate Sink
Lower Gate Source
Lower Gate Sink
RUGATEsk VUGATE − VPHASE = 0.1V, I = 50mA
ILGATEsr
VCC = 12V
RLGATEsk VLGATE = 0.1V, I = 50mA
-1
--
2.25
1.2
1
4
-2
Ω
A
Ω
Under Voltage Protection (UVP)
V FB_UVP
Sweep VFB
68
75
82
%
Over Voltage Protection
V FB_OVP
Sweep VFB (After POR)
115
125
130
%
Over Voltage Protection
V pre_OVP
Sweep VFB (Before POR)
--
130
--
%
LGATE OC Setting Current
IOCSET
22
25
28
μA
Over Temperature Protection
T OTP
--
165
--
°C
1
3
5
1
4
7
0.7
2.5
4
--
--
0.2
Protection
RT8108A/B
Soft-Start
Interval
RT8108C/D
T SS
Measure FB from 10% to 90%
RT8108E/F
COMP/SD Shutdown Threshold
V SD
ms
V
Note 1. Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device.
These are stress ratings only, and functional operation of the device at these or any other conditions beyond those
indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating
conditions for extended periods may affect device reliability.
Note 2. θJA is measured in the natural convection at TA = 25°C on a high effective thermal conductivity test board (4 Layers, 2S2P)
of JEDEC 51-7 thermal measurement standard. The case point of θJC is on the exposed pad of the package.
Note 3. Devices are ESD sensitive. Handling precaution is recommended.
Note 4. The device is not guaranteed to function outside its operating conditions.
.
DS8108-03
September 2011
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RT8108
Typical Operating Characteristics
Efficiency vs. Load Current
Output Voltage vs. Load Current
100
1.210
90
1.206
Output Voltage (V)
Efficiency (%)
80
70
60
50
40
30
1.202
1.198
20
1.194
10
VIN = VCC = 12V
VIN = VCC = 12V
0
1.190
0
5
10
15
20
25
30
0
5
10
Load Current (A)
15
20
25
Load Current (A)
Reference Voltage vs. Temperature
Frequency vs. Temperature
0.605
400
350
0.603
Frequency (kHz)11
Reference Voltage (V)
0.604
0.602
0.601
0.600
0.599
300
250
200
0.598
VIN = VCC = 12V, No Load
0.597
VIN = VCC = 12V, No Load
150
-50
-25
0
25
50
75
100
125
-50
Temperature (°C)
VOUT
(1V/Div)
VIN
(10V/Div)
VIN
(10V/Div)
V CC
(10V/Div)
UGATE
(20V/Div)
V CC
(10V/Div)
UGATE
(20V/Div)
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25
50
75
100
125
Power Off from VIN
VOUT
(1V/Div)
Time (4ms/Div)
0
Temperature (°C)
Power On from VIN
VIN = VCC = 12V, No Load
-25
VIN = VCC = 12V, No Load
Time (100ms/Div)
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RT8108
Power On from COMP/SD
Power Off from COMP/SD
VCOMP
(1V/Div)
VCOMP
(1V/Div)
VOUT
(1V/Div)
VOUT
(1V/Div)
UGATE
(20V/Div)
UGATE
(20V/Div)
LGATE
(10V/Div)
LGATE
(10V/Div)
VIN = VCC = 12V, No Load
Time (1ms/Div)
Time (20ms/Div)
Load Transient Response
Load Transient Response
VIN = VCC = 12V, ILOAD = 15A to 0A
L = 1uH, COUT = 1640uF
VIN = VCC = 12V, ILOAD = 0A to 15A
L = 1uH, COUT = 1640uF
VOUT_ac
(50mV/Div)
VOUT_ac
(50mV/Div)
UGATE
(20V/Div)
UGATE
(20V/Div)
I LOAD
(10A/Div)
I LOAD
(10A/Div)
Time (10μs/Div)
Time (10μs/Div)
Over Current Protection
Over Voltage Protection
VFB
(1V/Div)
IL
(10A/Div)
VOUT
(1V/Div)
VOUT
(1V/Div)
UGATE
(20V/Div)
UGATE
(20V/Div)
LGATE
(10V/Div)
VCC = 12V, IOCSET = 15A
Time (10ms/Div)
DS8108-03
VIN = VCC = 12V, No Load
September 2011
LGATE
(10V/Div)
VIN = VCC = 12V, No Load
Time (20ms/Div)
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RT8108
Application Information
Function Description
The RT8108 series are single-phase synchronous buck
PWM controllers with embedded MOSFET drivers. The
MOSFET drivers are designed with high-current driving
capability to support up to 12V+12V bootstrapped voltage
for high efficiency power conversion. The RT8108 series
utilize voltage-mode control scheme, which is implemented
with a voltage error amplifier to provide a simple control
loop. A fixed frequency oscillator (200kHz/300kHz/500kHz,
typical) is integrated to eliminate external component
count. The soft-start function is also integrated to eliminate
the external timing capacitor. The RT8108 series provide
full protection functions to protect the load. The feedback
voltage at the FB pin is monitored for over-voltage protection
and under-voltage protection. An internal 0.6V/0.8V
reference allows the output voltage to be precisely regulated
for low output voltage applications. An elaborately designed
control circuit allows the converter to power up with prebiased output voltage to avoid negative voltage damage to
the load. The RT8108 series use RDS(ON) current-sensing
technique, which is lossless and cost-effective. Inductor
current information is monitored by the voltage across
RDS(ON) of the low-side MOSFET for over current protection.
Power-up
The power on reset (POR) circuit monitors the supply
voltage of the controller (VCC). If VCC exceeds the POR
rising threshold voltage, the controller is initiated. The
controller sets the over current protection threshold prior
to the beginning of soft start. If VCC falls below the POR
falling threshold during normal operation, all MOSFETs
stop switching and the controller is reset. The POR rising
and falling threshold has a hysteresis to prevent noisecaused reset.
Soft-start
The RT8108 series provide soft-start function internally.
The soft-start function is used to prevent the large inrush
current while the converter is powered-up. An internal
current source charges the internal soft-start capacitor
such that the internal soft-start voltage ramps up in a
monotone. The FB voltage will track the internal soft-start
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8
voltage during the soft-start interval. After the internal softstart voltage exceeds the reference voltage, the FB voltage
no longer tracks the soft-start voltage but follows the
reference voltage. Therefore, the duty cycle of thr UGATE
signal at power up is limited and so does the input current.
Power-up with Pre-biased Voltage
Generally, if the output voltage is not initially zero at powerup, or the output capacitor is pre-charged, the voltage at
FB pin is not equal to zero. The controller will turn on the
low-side MOSFET to discharge the output capacitor, forcing
the feedback voltage to follow the reference voltage. Large
current is then drawn from the output capacitor while
discharging. The discharge current depends on the
inductance and the output capacitance. Output voltage may
oscillate and be negative.
The negative output voltage could damage the load. The
RT8108 series implement elaborate control circuits to
prevent the negative voltage when the converter is poweredup with pre-biased voltage on the output capacitor. Figure
1 shows the waveform that converter is powered-up at no
load with pre-biased output voltage. The output voltage rises
from its pre-charged initial value during soft-start without
being pulled down.
VCOMP
(2V/Div)
VOUT
(1V/Div)
UGATE
(20V/Div)
LGATE
(10V/Div)
Time (1ms/Div)
Figure 1. Power Up with Pre-Biased Output Voltage
COMP/SD Enable/Disable
The COMP/SD pin can also be used to enable or to disable
the controller. Pull down COMP/SD pin below the shutdown
level VSHDN can disable the controller. When the controller
is disabled, UGATE signal goes low first and then LGATE
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RT8108
signal also goes low after a short delay time. In practical
applications, connect a small signal MOFSET to
COMP/SD pin to pull down the COMP/SD voltage to
implement the enable/disable function.
Over Voltage Protection (OVP)
The output voltage is scaled by the divider resistors and
fed back to the FB pin. The voltage on the FB pin will be
compared to the internal reference voltage VREF for voltagerelated protection functions, including over voltage
protection and under voltage protection. If the FB voltage
is higher than the OVP threshold during operation, OVP
will be triggered. When OVP is triggered, UGATE will go
low and LGATE will go high to discharge the output
capacitor. Once OVP is triggered, controller will be latched
unless VCC POR is detected again.
Besides, the RT8108 series also provide OVP even if VCC
is below the POR threshold. This can protect the load
even if the high-side MOSFET is shorted before the poweron-reset. If the FB voltage is higher than the OVP threshold
while VCC rises but not exceeds the POR threshold, OVP
will be triggered. The LGATE signal will go high to discharge
the output capacitor.
current sensing, the voltage across the low-side MOSFET
is sampled and held after low-side MOSFET is turned on.
This sampled and held voltage represents the inductor peak
current and is compared to the user-programmed protection
level.
Once the inductor current exceeds the protection level,
OCP will be triggered. When the OCP is triggered, both
UGATE and LGATE go low to stop the energy transferring
to the load. Like UVP, the OCP is a continuing hiccupped
protection. The soft start will be initiated again after a
specific period of time (4*Tss, typical). If OCP situation is
not removed, controller will always try to restart.
OCP Setting
The RT8108 series employ an elaborate topology for OCP
setting, which eliminates controller pin count. Connect a
resistor from LGATE to GND to set the OCP level as shown
in Figure 2.
5V
IOCSET
+
OC
-
Under Voltage Protection (UVP)
The voltage on the FB pin is also monitored for under voltage
protection. If the FB voltage is lower than the UVP threshold
during normal operation, UVP will be triggered. When UVP
is triggered, both UGATE and LGATE go low. Unlike OVP,
UVP is not a latched protection. The controller will begin
soft start again after a specific period of time (~40ms).
Furthermore, the controller will enter the hiccup mode and
always try to restart if UVP situation is not removed. The
UVP is reset by detecting VCC POR again. Unlike OVP,
the output voltage is monitored for UVP only after softstart completes.
Over Current Protection (OCP)
The RT8108 series sense output current through low-side
MOSFET RDS(ON) for over current protection. When the
LGATE is turned on, the controller monitors voltage across
the low-side MOSFET. The lossless RDS(ON) current sensing
technique is cost-effective, because no external component
is required. The RT8108 series utilize cycle-by-cycle peak
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-1
PHASE
Sample
& Hold
LGATE
ROCSET
POR
Delay
Figure 2. OCP Setting
When the VCC exceeds the POR threshold at power up,
LGATE is internally floating and enters tri-state. An internal
current source I OCSET then flows through R OCSET to
determine the OCP threshold voltage. The voltage across
the ROCSET is stored as the over current level for OCP.
After that, the current source is switched off, and LGATE
leaves the tri-state and prepared for the soft-start. Therefore,
no extra pin is required to set the OCP threshold. The
internal current source IOC is only active for a short period
of time after VCC POR. The ROCSET can be determined
using the following equation.
ROCSET =
RDS(ON) × IMAX
2 x IOCSET
where IOCSET is 25uA (typical), IMAX represents the allowed
maximum inductor peak current.
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RT8108
MOSFET Drivers
The RT8108 series integrate high-current gate drivers for
MOSFETs to obtain high-efficiency power conversion in
synchronous buck topology. A dead time is used to prevent
the crossover conduction for the high-side and low-side
MOSFETs. Because both the two gate signals are off
during the dead time, the inductor current freewheels
through the body diode of the low-side MOSFET. The
freewheeling current and the forward voltage of the body
diode contribute to the power loss. The RT8108 series
employ a constant dead time control scheme to ensure
safe operation without sacrificing efficiency. Furthermore,
an elaborate logic circuit is implemented to prevent the
cross-conduction between MOSFETs.
For high output current applications, two or more power
MOSFETs are paralleled to have reduced RDS(ON). The gate
driver needs to provide more current to switch on/off these
paralleled MOSFETs. Gate driver with lower source/sink
current capability results in longer rising/ falling time in
gate signals, and therefore the higher switching loss.
The RT8108 series employ embedded high-current gate
drivers to obtain high-efficiency power conversion. The
embedded drivers contribute to the majority of the controller
power dissipation. If no gate resistor is used, the power
dissipation of the controller can be approximately calculated
using the following equation.
PSW = FSW x (Qg_High-Side x VBOOT + Qg_Low-Side
x VDrive_Low-Side )
inductors can save board space especially when the height
has limitation.
Additionally, larger inductance results in lower ripple current,
and therefore the lower power loss. However, the inductor
current rising time increases with inductance value. This
means the inductor will have a longer charging time before
its current reaches the required output current. Since the
response time is increased, the transient response
performance will be decreased. Therefore, the inductor
design is a trade-off between performance, size and cost.
In general, inductance is designed such that the ripple
current ranges between 20% to 30% of full load current.
The inductance can be calculated using the following
equation.
LMIN =
VIN − VOUT
V
× OUT
FSW × k × IOUT_Full Load
VIN
where k is 0.2 to 0.3.
Input Capacitor Selection
Voltage rating and current rating are the key parameters in
selecting input capacitor. The voltage rating must be 1.25
times greater than the maximum input voltage to ensure
enough room for safe operation. Generally, input capacitor
has a voltage rating of 1.5 times greater than the maximum
input voltage is a conservatively safe design.
The input capacitor is used to supply the input RMS
current, which can be approximately calculated using the
following equation.
VOUT ⎛ VOUT ⎞
× 1−
VIN ⎜⎝
VIN ⎟⎠
where VBOOT represents the voltage across the bootstrap
capacitor.
IRMS = IOUT ×
It is important to ensure the package can dissipate the
switching loss and have enough room for safe operation.
Refer to the manufacturer's databook for RMS current rating
to select proper capacitor. Use more than one capacitor
with low equivalent series resistance (ESR) in parallel to
form a capacitor bank is popular. Besides, placing ceramic
capacitor close to the drain of the high-side MOSFET is
helpful in reducing the input voltage ripple at heavy load.
Inductor Selection
Inductor plays an importance role in the buck converter
because the energy from the input power rail is stored in it
and then released to the load. From the viewpoint of
efficiency, the dc resistance (DCR) of inductor should be
as small as possible because inductor carries current all
the time. Using inductor that has lower DCR can obtain
higher efficiency. In addition, because inductor cost most
of the board space, its size is also important. Low profile
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Output Capacitor Selection
The output capacitor and the inductor form a low-pass filter
in the buck topology. The electrolytic capacitor is usually
used because it can provide large capacitance value. In
steady state condition, the output capacitor supplies only
AC ripple current to the load. The ripple current flows into/
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RT8108
out of the capacitor results in ripple voltage, which can be
determined using the following equation.
ΔVOUT_ESR = ΔIL x ESR
In addition, the output voltage ripple is also influenced by
the switching frequency and the capacitance value.
1
ΔVOUT_C = ΔIL ×
8 × COUT × FSW
In order to achieve fast transient response and accurate
output regulation, an adequate compensator design is
necessary. The goal of the compensation network is to
provide adequate phase margin (greater than 45 degrees)
and the highest 0dB crossing frequency. It is also
recommended to manipulate loop frequency response that
its gain crosses over 0dB at a slope of −20dB/dec.
V IN
The total output voltage ripple is the sum of VOUT_ESR and
VOUT_C.
If the specification for steady-state output voltage ripple is
known, the ESR can be determined using the above
equations.
OSC
Driver
PWM
Comparator
L OUT
-
ΔV OSC
Driver
+
V OUT
PHASE
C OUT
ESR
Another parameter that has influence on the output voltage
undershoot is the equivalent series inductance (ESL). The
rapid change in load current results in di/dt during transient.
Therefore, ESL contributes to part of the voltage
undershoot. Use capacitor that has low ESL to obtain better
transient performance. Generally, use several capacitors
connected in parallel can have better transient performance
than use single capacitor for the same total ESR.
Unlike the electrolytic capacitor, the ceramic capacitor has
relatively low ESR and can reduce the voltage deviation
during load transient. However, the ceramic capacitor can
only provide low capacitance value. Therefore, use a mixed
combination of electrolytic capacitor and ceramic capacitor
can also have better transient performance.
Feedback Loop Compensation
Figure 3 shows the voltage mode control loop for a buck
converter. The control loop consists of the modulator, output
LC filter and the compensator. The modulator is composed
of the PWM comparator and power MOSFETs. The PWM
comparator compares the error amplifier EA output (COMP)
with the oscillator (OSC) sawtooth wave to generate a PWM
signal. The MOSFETs is then switched on and off
according to the duty cycle of the PWM signal. The voltage
presented at PHASE node is a square wave of 0V to Vin.
The PHASE voltage is filtered by the output filter LOUT and
COUT to produce output voltage VOUT, which is fedback to
the inverting input of the error amplifier. The output voltage
is then regulated according to the reference voltage VREF.
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September 2011
Z FB
COMP
EA
+
Z IN
REF
Z FB
C2
C1
Z IN
C3
R2
V OUT
R3
R1
COMP
FB
EA
+
REF
Figure 3. Control Loop for Voltage Mode Buck Converter
1) Modulator and Output LC filter
Referring to Figure 3, the modulator gain is the input voltage
VIN divided by the peak to peak oscillator voltage VOSC as
shown as following Equation :
ModulatorGain =
VIN
ΔVOSC
where ΔVOSC = 1.5V (typ.)
The output LC filter introduces a double pole to the transfer
function, creating −40dB/decade gain slope above its corner
frequency, with a phase lag of 180 degrees. The frequency
at the double-pole of LC filter is expressed as follows.
fLC =
1
2π × LOUT × COUT
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11
RT8108
In addition, the ESR of the output capacitor introduces a
zero to the transfer function, creating a +20dB/dec gain
slope with a phase shift of 90 degree. The frequency of the
ESR zero is expressed as follows.
1
fESR =
2π × ESR × COUT
80 80
Loop Gain
60
40 40
Gain (dB)
2) Compensator
0
0
-20
Fugire 4 illustrates the type II compensator, which consists
of the error amplifier and the impedance ZC and ZF.
-60-60
10Hz
10vdb(vo)
ZC
C2
R2
R1
Modulator
Gain
-40-40
ZF
C1
Compensation
Gain
20
100Hz
vdb(comp2)100
vdb(lo)
1.0KHz
10KHz
1k
10k
Frequency (Hz)
Frequency
100KHz
100k
1.0MHz
1M
Figure 5. System Gain Bode Plot
V OUT
Layout Considerations
EA
+
COMP
V REF
FB
RF
Figure 4. Type II Compensator
Type II compensator provides two poles and one zero to
the system. The first pole is located at low frequency to
increase the dc gain for regulation accuracy. The location
of the other pole and the zero is expressed as follows.
fZ1 =
fP1 =
PCB layout is critical to high-current high-frequency
switching converter designs. A good layout can help the
controller to function properly and achieve expected
performance. On the other hand, PCB without a carefully
layout can radiate excessive noise, having more power
loss and even malfunction in the controller. In order to avoid
the above condition, the following general guidelines must
be followed in PCB layout.
`
Power stage components should be placed first. Place
the input bulk capacitors close to the high-side power
MOSFETs, and then locate the output inductor and finally
the output capacitors.
`
Place the ceramic capacitor physically close to the drain
of the high-side MOSFET. This can reduce the input
voltage drop when high-side MOSFET is turned on. If
more than one MOSFET is paralleled, each should have
its own individual ceramic capacitor.
`
Keep the high-current loops as short as possible. During
high speed switching, the current transition between
MOSFETs usually causes di/dt voltage spike due to the
parasitic components on PCB trace. Therefore, making
the trace length between power MOSFETs and inductors
wide and short can reduce the voltage spike and EMI.
`
Make MOSFET gate driver path as short as possible.
Since the gate driver uses narrow-width high-current
pulses to switch on/off the power MOSFET, the driver
path must be short to reduce the trace inductance. This
is especially important for low-side MOSFET, because
this can reduce the possibility of shoot-through.
1
2π × R2 × C2
1
2π × R2 × C1× C2
C1+ C2
Figure 5 shows the Bode plot for the gain of system. The
compensation gain determined by ZC and ZF should be
designed to have high crossover frequency (bandwidth) with
sufficient phase margin. In order to make the gain crosses
over 0dB at a slope of −20dB/dec, place the zero before
the LC double-pole frequency. Empirically, fz1 is placed at
75% of the LC double-pole frequency. Furthermore, the
bandwidth of the system is the factor that affects the
converter's transient performance. High bandwidth results
in fast transient response, but it often jeopardizes the
system stability. The bandwidth should be designed to be
less than 1/5 of the switching frequency. Properly adjust
R1 and R2 to change the mid-frequency gain to obtain the
required bandwidth. The pole at fp1 is usually placed at half
of the switching frequency to have sufficient phase margin
and attenuation at high frequency.
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12
DS8108-03
September 2011
RT8108
`
Providing enough copper area around the power
MOSFETs to help heat dissipation. Using thick copper
also reduces the trace resistance and inductance to have
better performance.
`
The output capacitors should be placed physically close
to the load. This can minimize the trace parasitic
components and improve transient response.
`
All small signal components should be located close to
the controller. The small signal components include the
feedback voltage divider resistors, compensator, function
setting components and high-frequency bypass
capacitors. The feedback voltage divider resistor and the
compensator must be placed close to FB pin and COMP
pin, because these pins are inherently noise-sensitive.
`
Voltage feedback path must be kept away from the
switching nodes. The noisy switching node is, for
example, the interconnection between high-side
MOSFET, low-side MOSFET and inductor. The feedback
path must be kept away from this kind of noisy node to
avoid noise pick-up.
`
A multi-layer PCB design is recommended. Make use
of one single layer as the ground and have separate
layers for power rail or signal that is suitable for PCB
design.
DS8108-03
September 2011
Figure 6. PCB Layout
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13
RT8108
Outline Dimension
H
A
M
J
B
F
C
I
D
Dimensions In Millimeters
Dimensions In Inches
Symbol
Min
Max
Min
Max
A
4.801
5.004
0.189
0.197
B
3.810
3.988
0.150
0.157
C
1.346
1.753
0.053
0.069
D
0.330
0.508
0.013
0.020
F
1.194
1.346
0.047
0.053
H
0.170
0.254
0.007
0.010
I
0.050
0.254
0.002
0.010
J
5.791
6.200
0.228
0.244
M
0.400
1.270
0.016
0.050
8-Lead SOP Plastic Package
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14
DS8108-03
September 2011
RT8108
H
A
M
EXPOSED THERMAL PAD
(Bottom of Package)
Y
J
X
B
F
C
I
D
Dimensions In Millimeters
Dimensions In Inches
Symbol
Min
Max
Min
Max
A
4.801
5.004
0.189
0.197
B
3.810
4.000
0.150
0.157
C
1.346
1.753
0.053
0.069
D
0.330
0.510
0.013
0.020
F
1.194
1.346
0.047
0.053
H
0.170
0.254
0.007
0.010
I
0.000
0.152
0.000
0.006
J
5.791
6.200
0.228
0.244
M
0.406
1.270
0.016
0.050
X
2.000
2.300
0.079
0.091
Y
2.000
2.300
0.079
0.091
X
2.100
2.500
0.083
0.098
Y
3.000
3.500
0.118
0.138
Option 1
Option 2
8-Lead SOP (Exposed Pad) Plastic Package
Richtek Technology Corporation
Richtek Technology Corporation
Headquarter
Taipei Office (Marketing)
5F, No. 20, Taiyuen Street, Chupei City
5F, No. 95, Minchiuan Road, Hsintien City
Hsinchu, Taiwan, R.O.C.
Taipei County, Taiwan, R.O.C.
Tel: (8863)5526789 Fax: (8863)5526611
Tel: (8862)86672399 Fax: (8862)86672377
Email: [email protected]
Information that is provided by Richtek Technology Corporation is believed to be accurate and reliable. Richtek reserves the right to make any change in circuit design,
specification or other related things if necessary without notice at any time. No third party intellectual property infringement of the applications should be guaranteed
by users when integrating Richtek products into any application. No legal responsibility for any said applications is assumed by Richtek.
DS8108-03
September 2011
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15