RICHTEK RT8204A

RT8204A
Single Synchronous Buck with LDO Controller
General Description
Features
The RT8204A PWM controller provides the high efficiency,
excellent transient response, and high DC output accuracy
needed for stepping down high voltage batteries to
generate low voltage CPU core, I/O, and chipset RAM
supplies in notebook computers.
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A built-in LDO controller can drive an external N-MOSFET
to provide a second output voltage from PWM output or
other power source. The RT8204A can provide adjustable
voltage down to 0.75V and maximum output voltage is
depended on the selected MOSFET. The internal 0.75V
reference voltage with ±1.5% accuracy provides tight
regulation for the output voltage. The independent enable
control, open drain power good indicator, under-voltage
protection and soft start make RT8204A to power the
system friendly. The RT8204A is available in WQFN-16L
3x3 package.
Applications
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Notebook Computers
CPU Core Supply
Chipset/RAM Supply as Low as 0.75V
Ultra-High Efficiency
` Resistor Programmable Current Limit by Low Side
RDS(ON) Sense (Lossless Limit) or Sense Resistor
(High Accuracy)
` Quick Load Step Response within 100ns
` 1% VOUT Accuracy Over Line and Load
` Adjustable 0.75V to 3.3V Output Range
` 3V to 26V Battery Input Range
` Resistor Programmable Frequency
` Over/Under Voltage Protection
` 2 Steps Current Limit During Soft-Start
` Drives Large Synchronous-Rectifier FETs
` Power Good Indicator
LDO Controller
` 1.5% Accuracy Over Line and Load
` Adjustabe Output Voltage down to 0.75V
` Independent Enable and Power Good Indicator
` Drive N-MOSFETs within Rail to Rail Controller
Voltage
` MLCC and POSCAP Stable
RoHS Compliant and 100% Lead (Pb)-Free
`
The constant-on-time PWM control scheme handles wide
input/output voltage ratios with ease and provides 100ns
“instant-on” response to load transients while maintaining
a relatively constant switching frequency.
The RT8204A achieves high efficiency at a reduced cost
by eliminating the current sense resistor found in
traditional current mode PWMs. Efficiency is further
enhanced by its ability to drive very large synchronous
rectifier MOSFETs. The buck conversion allows this device
to directly step down high voltage batteries for the highest
possible efficiency. The RT8204A is intended for CPU core,
chipset, DRAM, or other low voltage supplies as low as
0.75V.
PWM Controller
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Ordering Information
RT8204A
Package Type
QW : WQFN-16L 3x3 (W-Type)
Lead Plating System
P : Pb Free
G : Green (Halogen Free and Pb Free)
Note :
Richtek products are :
`
RoHS compliant and compatible with the current requirements of IPC/JEDEC J-STD-020.
`
Suitable for use in SnPb or Pb-free soldering processes.
Marking Information
For marking information, contact our sales representative
directly or through a Richtek distributor located in your
area.
DS8204A-05 April 2011
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RT8204A
Pin Configurations
TON
EN/DEM
LEN
BOOT
(TOP VIEW)
16 15 14 13
VOUT
VDD
FB
PGOOD
1
12
2
11
PHASE
OC
9 VDDP
GND
3
10
17
4
6
7
8
LPGOOD
LFB
LDRV
LGATE
5
UGATE
WQFN-16L 3x3
Typical Application Circuit
D1
BAT254
VDDP
5V
VIN
3V to 26V
C1
4.7µF
R4
1M
16
9
R2
100k
R1
10
C2
1µF
VDDP
2 VDD
4 PGOOD
PGOOD
15
CCM/DEM
14
LDO Enable
5
LDO PGOOD
R5
2.2
RT8204A
BOOT 13
TON
EN/DEM
UGATE 12
PHASE
C4
10µF
C3
0.1µF
Q1
AO4704
R6 0
11
LGATE 8
OC 10
Q2
AO4704
R7 10k
L1
2.4µH
C9
220µF
R8
R9
12k
C5
FB 3
C6
R10
20k
LEN
C13
0.1µF
LPGOOD
VOUT 1
R3
100k
VDDP
R11
GND
C7
33nF
LFB
6
C12
Q3
AO4404
LDRV 7
Exposed Pad(17)
VOUT1
1.2V
C8
R12
12k
C10
220µF
C11
10µF
VOUT2
1.05V
R13
30k
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DS8204A-05 April 2011
RT8204A
Functional Pin Description
Pin No.
Pin Name
1
VOUT
2
VDD
3
FB
4
PGOOD
5
LPGOOD
6
LFB
7
LDRV
8
LGATE
9
VDDP
10
OC
11
PHASE
12
UGATE
13
BOOT
14
LEN
15
EN/DEM
Pin Function
VOUT Sense Input. Connect to the output of PWM converter. VOUT is an
input of the PWM controller.
Analog Supply Voltage Input for the internal analog integrated circuit. Bypass
to GND with a 1μF ceramic capacitor.
VOUT Feedback Input. Connect FB to a resistor voltage divider from VOUT to
GND to adjust the output from 0.75V to 3.3V.
Power Good Signal Open-Drain Output of PWM Converter. This pin will be
pulled high when the output voltage is within the target range.
Power Good signal Open-Drain Output of LDO Regulator. This pin will be
pulled high when the output voltage is within the target range.
LDO Feedback Input. Connect LFB to a resistor voltage divider from VOUT to
GND to adjust the output greater than 0.75V.
Drive Signal for the LDO’s path MOSFET.
Low side N-MOSFET Gate-Drive Output for PWM. This pin swings between
GND and VDDP.
VDDP is the gate driver supply for the external MOSFETs. Bypass to GND
with a 1μF ceramic capacitor.
PWM Current Limit Setting and sense. Connect a resistor between OC to
PHASE for current limit setting.
Inductor Connection. This pin is not only the zero-current-sense input for the
PWM converter, but also the UGATE high side gate driver return.
High Side N-MOSFET Floating Gate-Driver Output for the PWM converter.
This pin swings between PHASE and BOOT.
Boost Capacitor Connection for PWM Converter. Connect an external
ceramic capacitor to PHASE and an external diode to VDDP.
LDO Enable Input with internal pull low resistor. LDO is enabled if LEN is
greater than the on level and disabled if LEN is less than the off level.
PWM Enable and Operation Mode Selection Input. Connect to VDD for diode
emulation mode, connect to GND for shutdown mode and floating the pin for
CCM mode.
16
TON
17 (Exposed Pad)
GND
DS8204A-05 April 2011
VIN Sense Input. Connect to VIN through a resistor. TON is an input of the
PWM controller.
Analog Ground and Power Ground. The exposed pad must be soldered to a
large PCB and connected to GND for maximum power dissipation.
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RT8204A
Function Block Diagram
PWM Controller
TRIG
On-time
Compute
1-SHOT
VOUT
TON
SS
(Internal)
- +
GM
+
-
-
R
Comp
S
+
BOOT
Q
DRV
UGATE
PHASE
0.75V VREF
Q
OV
+
115% VREF
Min. TOFF
TRIG
DRV
-
FB
-
70% VREF
UV
+
Latch
S1
Q
SS Timer
LGATE
PGND
Diode
Emulation
-
90% VREF
VDD
VDDP
1-SHOT
Latch
S1
Q
+
20µA
Thermal
Shutdown
+
OC
-
GND
PGOOD
EN/DEM
LDO Controller
SS
LEN
0.75V VREF
SS ramp
LFB
+
-
X1
LDRV
LPGOOD
-
90% VREF
+
-
50% VREF
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DS8204A-05 April 2011
RT8204A
Absolute Maximum Ratings
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(Note 1)
Input Voltage, TON to GND ---------------------------------------------------------------------------------------------BOOT to GND -------------------------------------------------------------------------------------------------------------PHASE to BOOT ---------------------------------------------------------------------------------------------------------PHASE to GND
DC ----------------------------------------------------------------------------------------------------------------------------<20ns -----------------------------------------------------------------------------------------------------------------------VDD, VDDP, VOUT, EN/DEM, LEN, LFB, FB, PGOOD, LPGOOD, LDRV to GND ----------------------UGATE to PHASE
DC ----------------------------------------------------------------------------------------------------------------------------<20ns -----------------------------------------------------------------------------------------------------------------------OC to GND -----------------------------------------------------------------------------------------------------------------LGATE to GND
DC ----------------------------------------------------------------------------------------------------------------------------<20ns -----------------------------------------------------------------------------------------------------------------------Power Dissipation, PD @ TA = 25°C
WQFN-16L 3x3 -----------------------------------------------------------------------------------------------------------Package Thermal Resistance (Note 2)
WQFN-16L 3x3, θJA ------------------------------------------------------------------------------------------------------WQFN-16L 3x3, θJC -----------------------------------------------------------------------------------------------------Lead Temperature (Soldering, 10 sec.) ------------------------------------------------------------------------------Junction Temperature ----------------------------------------------------------------------------------------------------Storage Temperature Range -------------------------------------------------------------------------------------------ESD Susceptibility (Note 3)
HBM (Human Body Mode) ---------------------------------------------------------------------------------------------MM (Machine Mode) ------------------------------------------------------------------------------------------------------
Recommended Operating Conditions
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−0.3V to 32V
−0.3V to 38V
−6V to 0.3V
−0.3V to 32V
−8V to 38V
−0.3V to 6V
−0.3V to 6V
−5V to 7.5V
−0.3V to 28V
−0.3V to 6V
−2.5V to 7.5V
1.471W
68°C/W
7.5C/W
260°C
150°C
−65°C to 150°C
2kV
200V
(Note 4)
Input Voltage, VIN ---------------------------------------------------------------------------------------------------------Supply Voltage, VDD, VDDP ---------------------------------------------------------------------------------------------Junction Temperature Range -------------------------------------------------------------------------------------------Ambient Temperature Range --------------------------------------------------------------------------------------------
3V to 26V
4.5V to 5.5V
−40°C to 125°C
−40°C to 85°C
Electrical Characteristics
(VDD = VDDP = 5V, VIN = 15V, VOUT = 1.25V, EN/DEM = VDD, RTON = 1MΩ, TA = 25°C, unless otherwise specified)
Parameter
Symbol
Test Conditions
Min
Typ
Max
Unit
--
--
1250
μA
μA
PWM Controller
VDD + VDDP, FB = 0.8V, forced above
Quiescent Supply Current
the regulation point
TON Operating Current
Shutdown Current
ISHDN
RTON = 1MΩ
VDD + VDDP
--
15
--
--
1
10
TON
--
1
--
−10
−1
--
EN/DEM = 0V
μA
To be continued
DS8204A-05 April 2011
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5
RT8204A
Parameter
Min
Typ
Max
Unit
0.742
−1
0.75
0.1
0.758
1
V
μA
0.75
--
3.3
V
267
334
401
ns
250
400
550
ns
--
20
--
Ω
LGATE = High
GND to OC
PHASE to GND, EN/DEM = 5V
18
−10
−10
20
---
22
10
5
μA
mV
mV
GND to PHASE, R ILIM = 2.5kΩ
GND to PHASE, R ILIM = 10kΩ
35
170
60
50
200
70
65
230
80
10
15
20
%
--
20
--
μs
4.1
4.3
4.5
V
--
1.35
--
ms
--
3.1
--
ms
Thermal Shutdown
--
155
--
°C
Thermal Shutdown Hysteresis
--
10
--
°C
-----
1.5
1.5
1.5
0.6
5
5
5
2.5
Ω
Ω
Ω
Ω
--
1
--
A
-----
1
3
30
30
-----
A
A
EN/DEM Low
EN/DEM High
-2.9
---
0.8
--
EN/DEM Float
EN/DEM = VDD
EN/DEM = 0
--−5
2
1
−1
-5
--
FB Reference Voltage
FB Input Bias Current
Symbol
V FB
Test Conditions
V DD = 4.5 to 5.5V
FB = 0.75V
Output Voltage Range
V IN = 15V, V OUT = 1.25V, RTON =
1MΩ
On-Time
Minimum Off-Time
V OUT Shutdown Discharge
Resistance
EN/DEM = GND
Current Sensing
ILIM Source Current
Current Comparator Offset
Zero Crossing Threshold
Fault Protection
Current Limit Sense Voltage
VRILIM
Output UV Threshold
OVP Threshold
OV Fault Delay
VDD UVLO Threshold
Soft-Start Ramp Time
UV Blank Time
With respect to error comparator
threshold
FB forced above OV threshold
Rising edge, Hysteresis = 20mV,
PWM disabled below this level
From EN high to internal VREF
reach 0.71V (0Æ95%)
From EN signal going high
mV
%
Driver On-Resistance
UGATE Driver Pull Up
UGATE Driver Sink
LGATE Driver Pull Up
LGATE Driver Pull Down
UGATE Driver Source/Sink
Current
LGATE Driver Source Current
LGATE Driver Sink Current
Dead Time
BOOT to PHASE forced to 5V
RUGATEsk BOOT to PHASE forced to 5V
LGATE, High State (Source)
LGATE, Low State (Sink)
UGATE forced to 2.5V,
BOOT to PHASE forced to 5V
LGATE forced to 2.5V
LGATE forced to 2.5V
LGATE Rising (PHASE = 1.5V)
UGATE Rising
ns
Logic I/O
Logic Input Low Voltage
Logic Input High Voltage
Logic Input Current
V
V
μA
To be continued
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DS8204A-05 April 2011
RT8204A
Parameter
Symbol
Test Conditions
Min
Typ
Max
Unit
−13
−10
−7
%
--
2.5
--
μs
---
---
0.4
1
V
μA
--
--
400
μA
--
--
5
μA
4.1
--
4.5
V
PGOOD (upper side threshold decide by OV threshold)
Measured at FB with respect to
reference, no load. Hysteresis = 3%
Falling edge, FB forced below
PGOOD trip threshold
ISINK = 1mA
High state, forced to 5V
Trip Threshold (Falling)
Fault Propagation Delay
Output Low Voltage
Leakage Current
LDO Controller
Quiescent Current
IQ
Shut-down Current
ISHDN
PWM off, LDO on, IOUT = 0mA
Input Voltage UVLO
LEN Logic High Voltage
VLEN_H
2
--
--
V
LEN Logic Low Voltage
VLEN_L
--
--
0.8
V
LEN Input Current
ILEN
--
--
10
μA
LFB Reference Voltage
VLFB
0.739
0.75
0.761
V
LFB Input Current
ILFB
−1
--
1
μA
LDRV Output Sourcing
Current
Sinking
ILDRV_sr
VLFB = 0.72V
1.4
2
--
ILDRV_sk
VLFB = 0.78V
1.4
2
--
Measured at LFB pin
40
50
60
%
--
2.5
--
μs
87
90
93
%
--
2.5
--
μs
--
--
0.4
V
Output UVP Threshold
LEN = 5V (Internal pull low)
UVP Propagation Delay
PGOOD Threshold (Falling)
PGOOD Low Voltage
Measured at LFB pin
Falling edge, FB forced below
PGOOD trip threshold
ISINK = 1mA
PGOOD Leakage Current
High state, forced to 5V
PGOOD Propagation Delay
Thermal Shutdown
Thermal Shutdown
Hysteresis
mA
--
--
1
μA
--
155
--
°C
--
10
--
°C
Note 1. Stresses listed as the above “Absolute Maximum Ratings” may cause permanent damage to the device. These are for
stress ratings. 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 remain possibility to affect device reliability.
Note 2. θJA is measured in the natural convection at T A = 25°C on a low effective thermal conductivity test board of
JEDEC 51-3 thermal measurement standard. The case point of θJC is on the expose pad for the WQFN package.
Note 3. Devices are ESD sensitive. Handling precaution is recommended.
Note 4. The device is not guaranteed to function outside its operating conditions.
DS8204A-05 April 2011
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RT8204A
Typical Operating Characteristics
VOUT1 Efficiency vs. Load Current
90
275
Switching Frequency (kHz)
300
80
Efficiency (%)
Switching Frequency vs. Output Current
100
DEM
70
60
PWM
50
40
30
20
10
0.01
0.1
1
PWM
225
200
175
150
DEM
125
100
75
50
25
VIN = 8V
0
0.001
250
0
0.001
10
VIN = 8V
0.01
VOUT1 Efficiency vs. Load Current
90
275
Efficiency (%)
Switching Frequency (kHz)
300
DEM
PWM
60
50
40
30
20
10
0.01
0.1
1
250
225
PWM
200
175
150
DEM
125
100
75
50
25
VIN = 12V
0
0.001
0
0.001
10
VIN = 12V
0.01
90
275
Efficiency (%)
Switching Frequency (kHz)
300
70
PWM
60
50
40
30
20
10
0
0.001
VIN = 24V
0.01
0.1
Load Current (A)
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Switching Frequency vs. Output Current
VOUT1 Efficiency vs. Load Current
100
DEM
0.1
Output Current (A)
Load Current (A)
80
10
Switching Frequency vs. Output Current
100
70
1
Output Current (A)
Load Current (A)
80
0.1
1
10
250
225
200
PWM
175
150
DEM
125
100
75
50
25
0
0.001
VIN = 24V
0.01
0.1
1
10
Output Current (A)
DS8204A-05 April 2011
RT8204A
Standby Current vs. Input Voltage
LDO Output Voltage vs. Output Current
400
1.0540
390
380
Standby Current (uA)
Output Voltage (V)
1.0535
1.0530
1.0525
1.0520
1.0515
1.0510
370
360
350
340
330
320
310
300
1.0505
290
VIN = 1.25V
1.0500
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
7
5
9
11
13
15
17
19
Output Current (A)
Input Voltage (V)
Shutdown Current vs. Input Voltage
Power On from EN
3.0
Shutdown Current (uA)
EN = 5V, No Load
280
21
23
25
PWM-Mode
2.5
VOUT
(1V/Div)
2.0
PHASE
(10V/Div)
1.5
1.0
EN/DEM
(2V/Div)
0.5
EN = GND, No Load
PGOOD
(5V/Div)
0.0
7
9
11
13
15
17
19
21
23
25
VIN = 12V, EN = Floating, No Load
Time (800μs/Div)
Input Voltage (V)
Power On from EN
Power Off from EN
DEM-Mode
VOUT
(1V/Div)
VOUT
(1V/Div)
PHASE
(10V/Div)
EN/DEM
(2V/Div)
UGATE
(20V/Div)
EN/DEM
(5V/Div)
PGOOD
(5V/Div)
VIN = 12V, EN = 5V, No Load
Time (800μs/Div)
DS8204A-05 April 2011
LGATE
(5V/Div)
VIN = 12V, EN = Floating, No Load
Time (4ms/Div)
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RT8204A
VOUT1 Load Transient Response
OVP
VOUT_ac
(50mV/Div)
VOUT
(1V/Div)
I LOAD
(5A/Div)
UGATE
(20V/Div)
UGATE
(10V/Div)
LGATE
(5V/Div)
LGATE
(5V/Div)
VIN = 12V, EN = Floating, IOUT1 = 0A to 6A
VIN = 12V, EN = 5V, No Load
Time (10μs/Div)
Time (40μs/Div)
UVP
Power On in Short Condition
VIN = 12V, EN = Floating, VOUT1 Short
VOUT
(1V/Div)
VOUT
(1V/Div)
Inductor
Current
(10A/Div)
I LOAD
(10A/Div)
UGATE
(20V/Div)
UGATE
(20V/Div)
LGATE
(5V/Div)
LGATE
(5V/Div)
VIN = 12V, EN = Floating, No Load
Time (20μs/Div)
Time (800μs/Div)
LDO Load Transient Response
LDO Power On from LEN
VIN = 1.25V, COUT = 10μF x 2, IOUT2 = 0.1A to 4A
VOUT
(1V/Div)
VOUT_ac-coupled
(100mV/Div)
LDRI
(2V/Div)
LDRI
(2V/Div)
LEN
(5V/Div)
I LOAD
(5A/Div)
LPGOOD
(5V/Div)
Time (100μs/Div)
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VIN = 1.25V, COUT = 10μF x 2, No Load
Time (100μs/Div)
DS8204A-05 April 2011
RT8204A
LDO Short-Circuit Protection
VOUT
(1V/Div)
LDRI
(5V/Div)
I LOAD
(20A/Div)
LPGOOD
(5V/Div)
VIN = 1.25V, VOUT2 Short, COUT = 10μF x 2
Time (100μs/Div)
DS8204A-05 April 2011
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RT8204A
Application Information
The RT8204A PWM controller provides the high efficiency,
excellent transient response, and high DC output accuracy
needed for stepping down high voltage batteries to
generate low voltage CPU core, I/O, and chipset RAM
supplies in notebook computers. Richtek's Mach
Response TM technology is specifically designed for
providing 100ns “instant-on” response to load steps while
maintaining a relatively constant operating frequency and
inductor operating point over a wide range of input voltages.
The topology circumvents the poor load transient timing
problems of fixed-frequency current mode PWMs while
avoiding the problems caused by widely varying switching
frequencies in conventional constant-on-time and constantoff-time PWM schemes. The DRV TM mode PWM
modulator is specifically designed to have better noise
immunity for such a single output application.
PWM Operation
The Mach ResponseTM, DRVTM mode controller relies on
the output filter capacitor's effective series resistance
(ESR) to act as a current-sense resistor, so the output
ripple voltage provides the PWM ramp signal. Refer to the
function diagrams of RT8204A, the synchronous high side
MOSFET is turned on at the beginning of each cycle.
After the internal one-shot timer expires, the MOSFET is
turned off. The pulse width of this one shot is determined
by the converter's input and output voltages to keep the
frequency fairly constant over the input voltage range.
Another one-shot sets a minimum off-time (400ns typ.).
On-Time Control (TON)
The on-time one-shot comparator has two inputs. One
input looks at the output voltage, while the other input
samples the input voltage and converts it to a current.
This input voltage proportional current is used to charge
an internal on-time capacitor. The on-time is the time
required for the voltage on this capacitor to charge from
zero volts to VOUT, thereby making the on-time of the high
side switch directly proportional to output voltage and
inversely proportional to input voltage. The implementation
results in a nearly constant switching frequency without
the need of a clock generator.
TON = 3.85p x RTON x VOUT / (VIN − 0.5)
And then the switching frequency is :
Frequency = VOUT / (VIN x TON)
RTON is a resistor connected from the input supply (VIN)
to the TON pin.
Mode Selection (EN/DEM) Operation
The EN/DEM pin enables the supply. When EN/DEM is
tied to VDD, the controller is enabled and operates in
diode-emulation mode. When the EN/DEM pin is floating,
the RT8204A will operate in forced-CCM mode.
Diode-Emulation Mode (EN/DEM = High)
In diode-emulation mode, RT8204A automatically reduces
switching frequency at light load conditions to maintain
high efficiency. This reduction of frequency is achieved
smoothly without increasing the VOUT ripple or load
regulation. As the output current decreases from heavy
load condition, the inductor current is also reduced, and
eventually comes to the point that its valley touches zero
current, which is the boundary between continuous
conduction and discontinuous conduction modes. By
emulating the behavior of diodes, the low side MOSFET
allows only partial of negative current when the inductor
freewheeling current reach negative. As the load current
is further decreased, it takes longer and longer to discharge
the output capacitor to the level than requires the next
“ON” cycle. The on-time is kept the same as that in the
heavy-load condition. In reverse, when the output current
increases from light load to heavy load, the switching
frequency increases to the preset value as the inductor
current reaches the continuous condition. The transition
load point to the light-load operation can be calculated as
follows (Figure 1) :
ILOAD ≈
IL
(VIN − VOUT )
× TON
2L
Slope = (V IN -V OUT) / L
iL, peak
iLoad = iL, peak / 2
0
tON
t
Figure 1. Boundary Condition of CCM/DEM
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DS8204A-05 April 2011
RT8204A
The switching waveforms may appear noisy and
asynchronous when light loading causes diode-emulation
operation, but this is a normal operating condition that
results in high light-load efficiency. Trade-off in DEM noise
vs. light-load efficiency is made by varying the inductor
value. Generally, low inductor values produce a broader
efficiency vs. load curve, while higher values result in higher
full-load efficiency (assuming that the coil resistance
remains fixed) and less output voltage ripple. The
disadvantages for using higher inductor values include
larger physical size and degrades load-transient response
(especially at low input-voltage levels).
Current sensing of the RT8204A can be accomplished in
two ways. Users can either use a current sense resistor
or the on-state of the low-side MOSFET (RDS(ON)). For
resistor sensing, a sense resistor is placed between the
source of low-side MOSFET and PGND (Figure 3(a)).
RDS(ON) sensing is more efficient and less expensive (Figure
3(b)). There is a compromise between current limit
accuracy and sense resistor power dissipation.
PHASE
LGATE
R ILIM
OC
Forced-CCM Mode (EN/DEM = floating)
The low noise, forced-CCM mode (EN/DEM = floating)
disables the zero-crossing comparator, which controls the
low-side switch on-time. This causes the low side gatedrive waveform to become the complement of the highside gate-drive waveform. This in turn causes the inductor
current to reverse at light loads as the PWM loop to
maintain a duty ratio VOUT/VIN. The benefit of forced-CCM
mode is to keep the switching frequency fairly constant,
but it comes at a cost: The no-load battery current can be
up to 10mA to 40mA, depending on the external
MOSFETs.
(a)
PHASE
LGATE
OC
R ILIM
(b)
Figure 3. Current-Sense Methods
ILoad
In both cases, the RILIM resistor between the OC pin and
PHASE pin sets the over current threshold. This resistor
RILIM is connected to a 20μA current source within the
RT8204A which is turned on when the low side MOSFET
turns on. When the voltage drop across the sense resistor
or low-side MOSFET equals the voltage across the RILIM
resistor, positive current limit will be activated. The high
side MOSFET will not be turned on until the voltage drop
across the sense element (resistor or MOSFET) falls
below the voltage across the RILIM resistor.
ILIM
Choose a current limit resistor by following equation :
Current Limit Setting (OCP)
The RT8204A has cycle-by-cycle current limiting control.
The current limit circuit employs a unique “valley” current
sensing algorithm. If the magnitude of the current-sense
signal at OC is above the current limit threshold, the PWM
is not allowed to initiate a new cycle (Figure 2).
IL
IL, peak
RILIM = ILIMIT x RSENSE / 20μA
t
0
Figure 2. Valley Current-Limit
DS8204A-05 April 2011
Carefully observe the PC board layout guidelines to ensure
that noise and DC errors do not corrupt the current-sense
signal seen by OC and PGND. Mount the IC close to the
low-side MOSFET and sense resistor with short, direct
traces, making a Kelvin sense connection to the sense
resistor.
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13
RT8204A
MOSFET Gate Driver (UGATE, LGATE)
POR, UVLO and Soft-Start
The high side driver is designed to drive high current, low
RDS(ON) N-MOSFETs. When configured as a floating driver,
5V bias voltage is delivered from VDDP supply. The average
drive current is proportional to the gate charge at
VGS = 5V times switching frequency. The instantaneous
drive current is supplied by the flying capacitor between
BOOT and PHASE pins.
Power-on reset (POR) occurs when VDD rises above to
approximately 4.3V, the RT8204A will reset the fault latch
and prepare the PWM for operation. If the VDD is below
4.1V (MIN), the VDD undervoltage-lockout (UVLO) circuitry
inhibits switching by keeping UGATE and LGATE low.
A dead time to prevent shoot through is internally
generated between high side MOSFET off to low side
MOSFET on, and low side MOSFET off to high side
MOSFET on.
The low side driver is designed to drive high current, low
RDS(ON) N-MOSFETs. The internal pull-down transistor that
drives LGATE low is robust, with a 0.6Ω typical onresistance. A 5V bias voltage is delivered form VDDP
supply. The instantaneous drive current is supplied by the
flying capacitor between VDDP and PGND.
For high current applications, some combinations of high
and low side MOSFETs might be encountered that will
cause excessive gate-drain coupling, which can lead to
efficiency-killing, EMI-producing shoot-through currents.
This is often remedied by adding a resistor in series with
BOOT, which increases the turn-on time of the high-side
MOSFET without degrading the turn-off time (Figure 4).
+5V
BOOT
Furthermore, the maximum allowed current limit is
segment in 2 steps during 1.35ms period.
Output Over Voltage Protection (OVP)
The output voltage can be continuously monitored for over
voltage protection. When the output voltage exceeds 15%
of the its setting voltage threshold, the over voltage
protection is triggered and the low side MOSFET is latched
on. This activates the low side MOSFET to discharge the
output capacitor.
The RT8204A is latched once OVP is triggered and can
only be released by VDD or EN/DEM power on reset. There
is a 20μs delay built into the over voltage protection circuit
to prevent false transitions.
V IN
R
UGATE
PHASE
Figure 4. The UGATE Rise Time Reduction
Power-Good Output (PGOOD)
The power good output is an open-drain output and requires
a pull-up resistor. When the output voltage is 15% above
or 10% below its set voltage, the PGOOD gets pulled
low. It is held low until the output voltage returns to within
these tolerances once more. In soft start, the PGOOD is
actively held low and is allowed to be pulled high until soft
start is over and the output reaches 93% of its set voltage.
There is a 2.5μs delay built into the PGOOD circuitry to
prevent false transition.
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14
A built-in soft-start is used to prevent the surge current
from power supply input after EN/DEM is enabled. It
clamps the ramping of internal reference voltage which is
compared with the FB signal. The typical soft-start duration
is 1.35ms.
Output Under Voltage Protection (UVP)
The output voltage can be continuously monitored for under
voltage protection. When the output voltage is less than
70% of its set voltage threshold, the under voltage
protection is triggered and then both UGATE and LGATE
gate drivers are forced low. In order to remove the residual
charge on the output capacitor during the under voltage
period, if the PHASE is greater than 1V, the LGATE is
forced high until PHASE is lower than 1V. There is 2.5μs
delay built into the under voltage protection circuit to
prevent false transitions. During the soft-start, the UVP
will be blanked around 3.1ms.
Output Voltage Setting (FB)
The output voltage can be adjusted from 0.75V to 3.3V by
setting the feedback resistor R1 and R2 (Figure 5). Choose
R2 to be approximately 10kΩ, and solve for R1 using the
equation :
DS8204A-05 April 2011
RT8204A
⎡
⎤
VOUT = VFB × ⎢1 + ⎛⎜ R1 ⎞⎟ ⎥
⎣ ⎝ R2 ⎠ ⎦
where VFB is 0.75V.
Note that in order for the device to regulate in a controlled
manner, the ripple content at the feedback pin, VFB, should
be approximately 15mV at minimum VBAT, and worst case
no smaller than 10mV. If Vripple at minimum VBAT is less
than 15mV, the above component values should be
revisited in order to improve this. Quite often a small
capacitor, C1, is required in parallel with the top feedback
resistor, R1, in order to ensure that VFB is large enough.
The value of C1 can be calculated as follows, where R2 is
the bottom feedback resistor.
Firstly calculating the value of Z1 required :
Z1 =
If RTON ≥ 2MΩ then TON
Where RTON is TON set resistor and the VOUT_FB is the
output signal of resistor divider. Since the switching
frequency is
VOUT
FS =
VIN × TON
If RTON < 2MΩ then
Secondly calculating the value of C1 required to achieve
this :
1 − 1
Z1 R1
C1 =
F
2 × π × fSW_VBAT(MIN)
)
RTON =
RTON =
VIN
BOOT
VOUT
VOUT
R1
C1
C2
R1
C2
R4
R2
GND
Figure 6. Output Voltage Setting for VOUT > 3.3V
Application
Output Inductor Selection
The switching frequency (on-time) and operating point (%
ripple or LIR) determine the inductor value as follows :
L=
FB
R3
V OUT_FB
FB
V IN
BOOT
V OUT
PHASE
VFB_VBAT(MIN) is the ripple voltage into FB pin in minimum
VBAT.
Z1
R TON
UGATE
fsw_VBAT(MIN) is the switching frequency in minimum VBAT;
PHASE
VOUT − 0.4
VOUT
1
×
×
VIN
VOUT_FB FS × 3.55p
V IN
⎡
⎤
⎢
⎥
⎢
⎥
R2
×⎢
⎥ V
1
⎢ R2+
⎥
1 + 2×π × f
⎢
SW_VBAT(MIN) × C1 ⎥
R1
⎣
⎦
where Vripple_VBAT(MIN) is the output ripple voltage in
minimum VBAT ;
V OUT
VOUT − 0.5
VOUT
1
×
×
VIN
VOUT_FB FS × 3.85p
If RTON ≥ 2MΩ then
Finally using the equation as follows to verify the value of
VFB :
VFB_VBAT(MIN) = Vripple_VBAT(MIN)
UGATE
RTON × VOUT_FB
VIN − 0.5
RTON × VOUT_FB
= 3.55p ×
VIN − 0.4
If RTON < 2MΩ then TON = 3.85p ×
For a given switching frequency, we can obtain the RTON
as below
R2 × V
( ripple_VBAT(MIN) − 0.015 ) Ω
0.015
(
For application that output voltage is higher than 3.3V,
user can also use a voltage divider to keep VOUT pin
voltage within 0.75V to 2.8V as shown in Figure 6. For
this case, TON can be determined as below :
TON × (VIN - VOUT )
LIR × ILOAD(MAX)
R2
GND
Figure 5. Setting The Output Voltage
DS8204A-05 April 2011
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15
RT8204A
Find a low pass inductor having the lowest possible DC
resistance that fits in the allowed dimensions. Ferrite cores
are often the best choice, although powdered iron is
inexpensive and can work well at 200kHz. The core must
be large enough and not to saturate at the peak inductor
current (IPEAK) :
IPEAK = ILOAD(MAX) + [(LIR / 2) x ILOAD(MAX)]
Output Capacitor Selection
The output filter capacitor must have ESR low enough to
meet output ripple and load transient requirement, yet have
high enough ESR to satisfy stability requirements. Also,
the capacitance value must be high enough to absorb the
inductor energy going from a full-load to no-load condition
without tripping the OVP circuit.
For CPU core voltage converters and other applications
where the output is subject to violent load transient, the
output capacitor's size depends on how much ESR is
needed to prevent the output from dipping too low under a
load transient. Ignoring the sag due to finite capacitance :
VP-P
ESR ≤
ILOAD(MAX)
In non-CPU applications, the output capacitor's size
depends on how much ESR is needed to maintain at an
acceptable level of output voltage ripple :
VP-P
ESR ≤
LIR × ILOAD(MAX)
Organic semiconductor capacitors or specially polymer
capacitors are recommended.
Output Capacitor Stability
Stability is determined by the value of the ESR zero relative
to the switching frequency. The point of instability is given
by the following equation :
fESR =
f
1
≤ SW
2 × π × ESR × COUT
4
Do not put high-value ceramic capacitors directly across
the outputs without taking precautions to ensure stability.
Large ceramic capacitors can have a high ESR zero
frequency and cause erratic and unstable operation.
However, it is easy to add sufficient series resistance by
placing the capacitors a couple of inches downstream from
the inductor and connecting VOUT or FB divider close to
the inductor.
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16
There are two related but distinct ways including doublepulsing and feedback loop instability to identify the
unstable operation.
Double-pulsing occurs due to noise on the output or
because the ESR is too low that there is not enough
voltage ramp in the output voltage signal. The “fools” the
error comparator into triggering a new cycle immediately
after 400ns minimum off-time period has expired. Doublepulsing is more annoying than harmful, resulting in nothing
worse than increased output ripple. However, it may
indicate the possible presence of loop instability, which
is caused by insufficient ESR.
Loop instability can result in oscillation at the output after
line or load perturbations that can trip the over voltage
protection latch or cause the output voltage to fall below
the tolerance limit.
The easiest method for stability checking is to apply a
very zero-to-max load transient and carefully observe the
output-voltage-ripple envelope for overshoot and ringing. It
helps to simultaneously monitor the inductor current with
AC probe. Do not allow more than one ringing cycle after
the initial step-response under- or over-shoot.
LDO Normal Operation
The RT8204A LDO controls an N-MOSFET to produce a
tightly regulated output voltage from higher supply voltage.
It takes 5V power supply for controller and draws maximally
400μA while operating.
The feedback voltage is regulated to compare with the
internal 0.75V reference voltage. To set the output voltage,
feedback the conjunction of a resistor voltage divider from
output node to ground for the LFB pin.
Depending upon the input voltage used for the device, the
LDRV pin can be pulled up near to VDD. Thus the device
can be used to regulate a large range of output voltage by
careful selection of the external MOSFETs.
A built-in active high enable control (LEN pin) is used to
turn the RT8204A LDO on. If this pin is pulled low, the
LDRV pin is pulled low, turning off the N-MOSFET. If this
pin is pulled higher than 2V, the LDRV pin is enabled.
DS8204A-05 April 2011
RT8204A
The RT8204A LDO contains a power good output pin
(LPGOOD pin) which is an open drain output that will be
pulled low if the output is below the power good threshold
(typically 90% of the programmed output voltage, or 93%
at the start up). The power good detection is active if the
RT8204A LDO is enabled.
The RT8204A LDO also includes a under voltage protection
circuit that monitors the output voltage. If the output voltage
drops below 50% (typical) of the nominal value, as would
occur during over current or short condition, the RT8204A
LDO will pull the LDRV pin low and latch off. The RT8204A
LDO is latched once the UVP is triggered and can only
be relieved by the VDD or LEN power-on reset.
moment. If both of these criteria are met, the output will
be shut down by means of the VDRV pulled to ground
immediately.
If the VDDP input is coming prior to the LDO_VIN, it could
accidentally meet the UVP fault protection. To avoid
entering UVP latch off, using enable control (LEN pin) to
turn the system on whenever all power supplies are ready.
Please see the power sequencing example as below
(Figure 7).
VDDP
VTH(UV) = 0.88V
LDO_VIN
LDO Driver and Stability Design
The drive output (LDRV pin) is sink/source capable. The
sink current is typically 2mA while the source current is
typically 2mA in normal operation.
The drive output is also used for stabilizing the loop of the
system using different type of the output capacitor. The
components listed in the table below should be used.
Table 1. LDO Configuration and Compensation
LDO Configuration
Input
Output
Voltage
Voltage
1.25V
Compensator
VTH(LEN) = 2V
LEN
VTH(LEN) occurs after VTH(UV)
is reached
RT8204A Supply Comes Up Before MOSFET Drain Supply
VDDP
VTH(UV) = 0.88V
LDO_VIN
VTH(LEN) = 2V
C7
C8
R11
1.05V
33nF
39pF
82Ω
1.5V
1.05V
33nF
47pF
43Ω
1.5V
1.25V
33nF
47pF
30Ω
1.8V
1.5V
33nF
39pF
100Ω
Note: test condition is output capacitor 220μF(ESR : 9
to 25mΩ) or 100μF(ESR : 9 to 15mΩ) + MLCC
10μFoutput current is from 0.1A to 5A
LDO Output Under Voltage Protection(UVP)
The RT8204A LDO has output under voltage protection
that looks at the output to see if it is :
(a) The LDO output voltage is less than 50% (typical) of
its nominal value and
LEN
VTH(LEN) occurs after VTH(UV) is
reached LEN rising with VDDP shown
MOSFET Drain Supply Comes Up Before RT8204A Supply
Figure 7. Power Supply Sequencing
LDO Output Voltage Setting
The LFB pin connects directly to the inverting input of the
error amplifier, and the output voltage is set using external
resistor R3 and R4 (Figure 8). The following equation is
for adjusting the output voltage.
⎡
⎤
VOUT = VLFB × ⎢1 + ⎛⎜ R3 ⎞⎟ ⎥
⎣ ⎝ R4 ⎠ ⎦
where VLFB is 0.75V (typ.).
(b) The VDRV is within 900mV (typical) of its maximum.
This provides inherent immunity to under voltage shut down
at start up since VDRV has a slow rate of rising at this
DS8204A-05 April 2011
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17
RT8204A
LDO_VIN
Layout Considerations
LDRV
LDO_VOUT
R3
Layout is very important in high frequency switching
converter design. If the Layout is designed improperly,
the PCB could radiate excessive noise and contribute to
the converter instability. Certain points must be considered
before starting a layout for the RT8204A.
LFB
`
Connect an RC low pass filter from VDDP to VDD, 1μF
and 10Ω are recommended. Place the filter capacitor
close to the IC.
`
Keep current limit setting network as close as possible
to the IC. Routing of the network should avoid coupling
to high voltage switching node.
`
Connections from the drivers to the respective gate of
the high side or the low side MOSFET should be as
short as possible to reduce stray inductance.
`
All sensitive analog traces and components such as
VOUT, FB, GND, EN/DEM, PGOOD, OC, VDD, and
TON should be placed away from high voltage switching
nodes such as PHASE, LGATE, UGATE, or BOOT
nodes to avoid coupling. Use internal layers as ground
planes and shield the feedback trace from power traces
and components.
`
Current sense connections must always be made using
Kelvin connections to ensure an accurate signal, with
the current limit resistor located at the device.
`
Power sections should connect directly to ground planes
using multiple vias as required for current handling
(including the chip power ground connections). Power
components should be placed to minimize loops and
reduce losses.
R4
Figure 8. LDO Output Voltage Setting
LDO Output Capacitor Selection
Low ESR capacitors such as Sanyo POSCAPs or
Panasonic SP-caps are recommended for bulk
capacitance, and ceramic bypass capacitors are
recommended for decoupling high frequency transients.
LDO Input Capacitor Selection
Low ESR capacitors such as Sanyo POSCAPs or
Panasonic SP-caps are recommended for the input
capacitors to provide better load transient response. If the
LDO input is connected from the output of buck converter
(VOUT1), a 0.1μF ceramic capacitor will sufficient.
LDO MOSFET Selection
Low threshold N-MOSFETs are required. For the device
to work under all operating conditions, a maximum RDS(ON)
must be met to ensure that the output will not go into
dropout :
RDS(ON)(MAX) =
VIN(MIN) − VOUT(MAX)
IOUT(PEAK)
Ω
Note that RDS(ON) must be met for operating temperature
range at the minimum VGS condition.
Power consumptions of the N-MOSFETs should be taken
into consideration for the selection of various package
types.
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18
DS8204A-05 April 2011
RT8204A
Outline Dimension
D
SEE DETAIL A
D2
L
1
E
E2
e
b
1
2
2
DETAIL A
Pin #1 ID and Tie Bar Mark Options
A
A1
1
A3
Note : The configuration of the Pin #1 identifier is optional,
but must be located within the zone indicated.
Dimensions In Millimeters
Dimensions In Inches
Symbol
Min
Max
Min
Max
A
0.700
0.800
0.028
0.031
A1
0.000
0.050
0.000
0.002
A3
0.175
0.250
0.007
0.010
b
0.180
0.300
0.007
0.012
D
2.950
3.050
0.116
0.120
D2
1.300
1.750
0.051
0.069
E
2.950
3.050
0.116
0.120
E2
1.300
1.750
0.051
0.069
e
L
0.500
0.350
0.020
0.450
0.014
0.018
W-Type 16L QFN 3x3 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.
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