ETC UP6161

www.datasheet4u.com
uP6161
Preliminary
Single 12V Input Supply Dual Regulator Synchronous-Buck-PWM and Linear-Regulator Controller
Features
General Description
The uP6161 integrates a high performance synchronousrectified buck controller and a linear-regulator controller.
This part works with a single +12V supply voltage and
delivers two high quality output voltages for both processing
unit and memory unit. An internal linear regulator provides
optimum 9V drive voltage for efficiency and thermal
management.
The buck controller features internal MOSFET drivers that
supports bootstrapped voltage for high efficiency power
conversion. The bootstrap diode is built-in to simplify the
circuit design and minimize external part count. It
incorporates simple, single feedback loop, voltage-control
with fast transient response.
The linear controller drives an external N-Channel MOSFET
with under voltage protection during both soft start and
normal operation.
Other features include adjustable operation frequency,
internal soft start, under voltage protection, adjustable over
current protection and shutdown function. With the above
function, this part provides customers a compact, well
protected and cost-effective solution. This part is available
in SOP-14 and QFN3x3 -16L packages.
Applications
† Power Supplies for Microprocessors or
Subsystem Power Supplies
† Cable Modems, Set Top Boxes, and DSL
Modems
† Operate with Single 12V Supply
† Self-Regulated 9V Drive Voltage
† Integrated Boot Diode
† Provide Two Regulated Voltages
† One Synchronous-Rectified Buck Controller
† One Linear Controller
† Both Controllers Drive N-Channel MOSFETs
† Smaller Converter Size
† Excellent Output Voltage Regulation
†
†
†
†
†
†
†
† 1.5% for Buck Controller
† 2% for Linear Controller
Simple Single-Loop Control Design
† Voltage-Mode PWM Control
† Fast Transient Response
† High-Bandwidth Error Amplifier
Lossless, Programmable Overcurrent Protection
† Uses Lower MOSFET RDS(ON)
Adjustable Frequency from 150kHz to 1MHz
Internal Soft Start for Both Outputs
Under Voltage Protection for Both Outputs
including Soft Start Cycle
SOP-14 and QFN3x3-16 packages
RoHS Compliant and 100% Lead Free
Ordering Information
Order Number Package Type
† Industrial Power Supplies; General Purpose
Supplies
uP6161S14
SOP - 14
† 12V Input DC-DC Regulators
uP6161Q
QFN3x3 - 16
† Low-Voltage Distributed Power Supplies
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
Remark
Note: uPI products are compatible with the current IPC/
JEDEC J-STD-020 and RoHS requirements. They are 100%
matte tin (Sn) plating and suitable for use in SnPb or Pbfree soldering processes.
1
www.datasheet4u.com
uP6161
Preliminary
11
LGATE
LDRV
5
10
PVCC9
LFB
6
9
VCC9
AGND
7
8
VCC12
FB
2
PHASE
4
1
13
FB
COMP
12
PGND
11
LGATE
PGND
LDRV
3
10
PVCC9
LFB
4
9
VCC9
AGND
SOP-14
8
PGND
VCC12
12
UGATE
3
14
COMP
7
PHASE
VCC12
13
BOOT
2
15
RT/DIS
6
UGATE
PGND
14
RT/DIS
1
5
BOOT
16
Pin Configuration
QFN3x3 – 16L
Typical Application Circuit
VIN1
+12V
VCC12
8
BOOT
PVCC9
10
1
UGATE
VCC9
14
9
5
uP6161S14
13
LDRV
VOUT2
VOUT1
PHASE
VIN2
LGATE
11
LFB
6
PGND
13
FB
4
R1
RT/DIS#
2
Disable
Enable
GND
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
COMP
7
3
R2
2
www.datasheet4u.com
uP6161
Preliminary
Functional Block Diagram
VCC9
SS3
SS2
SS1
Soft
Start
VCC5 Internal
POR &
Reference
Regulator
0.6V
Internal
Regulator
PVCC9
VOCP
0.6V
FB
VCC12
Enable &
Protection
Logic
BOOT
UGATE
0.4V
SS1
Gate
Control
Logic
0.8V
SS2
PHASE
PVCC9
LFB
0.8V
SS3
Oscillator
LGATE
LDRV
COMP
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
RT/DIS
GND
PGND
3
www.datasheet4u.com
Preliminary
uP6161
Functional Pin Description
Pin No.
SOP QFN
Pin
Name
Pin Function
1
15
Bootstrap Supply for the floating upper gate driver. Connect the bootstrap capacitor CBOOT
between BOOT pin and the PHASE pin to form a bootstrap circuit. The bootstrap capacitor
BOOT
provides the charge to turn on the upper MOSFET. Typical values for CBOOT range from 0.1uF
to 0.47uF. Ensure that CBOOT is placed near the IC.
2
16
RT/DIS
3
1
Error Amplifier Output. This is the output of the error amplifier (EA) and the non-inverting
COMP input of the PWM comparator. Use this pin in combination with the FB pin to compensate the
voltage-control feedback loop of the buck converter.
4
2
FB
Feedback Voltage for Buck Converter. This pin is the inverting input to the error amplifier.
A resistor divider from the output to GND is used to set the regulation voltage. Use this pin in
combi nati on wi th the C OMP pi n to compensate the voltage control feedback loop of the
converter.
5
3
LDRV
Driver Output for Linear Regulator. This pin provides the gate voltage for the linear regulator
pass transistor. Connect this pin to the gate of an external N-Channel MOSFET to form a linear
regulator.
6
4
LF B
Feedback Voltage for Linear Regulator. This pin is the inverting input to the error amplifier.
A resistor divider from the output to GND is used to set the regulation voltage.
7
5
AGND
Signal Ground for the IC. All voltages levels are measured with respect to this pin. Tie this
pin to the ground island/plane through the lowest impedance connection available.
8
7, 8
9
9
10
10
Pow er PVCC9. This is the output of the internal 9V linear regulator. It provides current required
PVCC9 fo r d ri vi ng N-C ha nne l MOS F E Ts o f b uc k c o nve rte r. A mi ni mum 1 uF c e ra mi c c a p a c i to r
physically near the IC is required for locally bypassing the input voltage.
11
11
Low er Gate D river Output. C onnect thi s pi n to the gate of lower MOS FE T. Thi s pi n i s
LGATE moni tored by the adapti ve shoot-through protecti on ci rcui try to determi ne when the lower
MOSFET has turn off.
12
6, 12
Frequency Setting and Chip Disable. A resistor to GND sets the operation frequency of
for the buck converter. Pulling this pin to GND disables both buck and linear regulators.
Supply Voltage. This is the power supply pin for the IC; it sources the internal 9V regulator
VCC12 used to the gate drivers. A minimum 1uF ceramic capacitor is required for locally bypassing
the input voltage.
VC C 9
VCC9. This pin supplies bias current for the IC. A minimum 1uF ceramic capacitor physically
near the IC is required for locally bypassing the input voltage.
PGND Pow er Ground for the IC.
13
13
PHASE Sw itch Node. Connect this pin to the source of the upper MOSFET and the drain of
the lower MOSFET. This pin is used as the sink for the UGATE driver, and to monitor the
voltage drop across the lower MOSFET for over current protection. This pin is also monitored
PHASE
by the adaptive shoot-through protection circuitry to determine when the upper MOSFET has
turned off. A Schottky diode between this pin and ground is recommended to reduce negative
transient voltage which is common in a power supply system.
14
14
U pper Gate D river Output. C onnect thi s pi n to the gate of upper MOS FE T. Thi s pi n i s
UGATE moni tored by the adapti ve shoot-through protecti on ci rcui try to determi ne when the upper
MOSFET has turned off.
Exposed Pad
Pow er Ground for the IC. For QFN package only. This exposed pad should be well soldered
to PCB for effective heat conduction. Connect the exposed pad the ground.
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
4
www.datasheet4u.com
uP6161
Preliminary
Functional Description
The buck controller features internal MOSFET drivers that
supports 12V + 12V bootstrapped voltage for high efficiency
power conversion. The bootstrap diode is built-in to simplify
the circuit design and minimize external part count. It
incorporates simple, single feedback loop, voltage-control
with fast transient response.
The linear controller drives an external N-Channel MOSFET
with undervoltage protection during both softstart and normal
operation.
Other features include adjustable operation frequency,
internal softstart, undervoltage protection, adjustable
overcurrent protection and shutdown function.
Supply Voltage
The uP6161 is designed to work with a single supply rail.
It integrates two linear regulators providing optimal supply
voltages for gate drivers and control circuitry respectively
as shown in Figure 1. The 9V linear regulator generates
9V PVCC9 for gate drives achieving optimum balance
between efficiency and thermal management. The 5V linear
regulator works with VCC9 input generates VCC5 for
internal control circuitry. If 12V driving voltage is preferred,
simply connect +12V to the PVCC9 pin and let VCC12
open.
+12V
VCC12
9V
Linear
Regulator
PVCC9
uP6161
Gate
Drivers
POR
Monitoring
VCC9
power on reset with typical rising threshold level as 7.5V.
All the three supply inputs require minimum 1uF ceramic
capacitors for local bypassing. Place the bypass capacitors
physically near the IC. No external bypass capacitor is
required for filtering the VCC5 voltage.
Bootstrap Circuitry
The uP6161 integrates MOSFET gate drives that are
powered from the PVCC9 pin and support 12V+12V driving
capability. A bootstrap diode is embedded to facilitates PCB
design and reduce the total BOM cost. Connect a ceramic
bootstrap diode between BOOT and PHASE pins to form a
bootstrap circuit for providing charge to turn on/off the upper
MOSFET. No external Schottky diode is required.
Converters that consist of uP6161 feature high efficiency
without special consideration on the selection of
MOSFETs.
Chip Enable and Frequency Setting
The RT/DIS is a multifunctional pin: chip shutdown and
frequency setting. Pulling low this pin to GND by an open
drain/collector transistor shuts down the uP6161 and
disables both buck and linear controllers.
The switching frequency is set by a resistor connecting to
the RT/DIS pin as:
fOSC =
23500000
+ 74000
RRT
(Hz)
Figure 2 shows the dependence between the resistor
chosen and the resulting switching frequency.
1000
Switching Frequency (kHz)
The uP6161 integrates a high performance synchronousrectified buck controller and a linear-regulator controller.
This part works with a single +12V supply voltage and
delivers two high quality output voltages for both processing
unit and memory unit. An internal linear regulator provides
optimum 9V drive voltage for efficiency and thermal
management.
100
5V
Linear
Regulator
10
Control
Circuitry
100
RRT (kohm)
1000
Figure 2. Switching Frequency vs. RRT
Soft Start
Figure 1. Supply Voltage Configuration
Once POR is acknowledged and RT/DIS pin is released,
Both PVCC9 and VCC9 are continuously monitored for
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
5
www.datasheet4u.com
uP6161
Preliminary
Functional Description
the uP6161 initiates its digital soft start cycle to prevent
surge current from power supply input during turn on
(referring to the Functional Block Diagram). The error
amplifiers are three-input devices. Reference voltage VREF
or the internal soft start voltage SS2/SS3 whichever is
smaller dominates the behavior of the non-inverting inputs
of the error amplifiers. SS2/SS3 internally ramps up to 0.8V
in 4096 cycles of the internal oscillator frequency after the
after the softstart cycle is initiated. Take 600kHz switching
frequency for example (1.67us per cycle), the ramp-up time
is about 6.8ms. Accordingly, the output voltages follow the
soft start signals SS2/SS3 and linearly ramp up to their
final level, resulting minimum inrush current from input
voltage.
The SS2/SS3 signals keep ramping up after it exceeds
the internal 0.8V reference voltages. However, the internal
0.8V reference voltages takes over the behavior of error
amplifier after SS > VREF. When the SS2/SS3 signal climb
to its ceiling voltage (5V), the uP6161 claims the end of
softstart cycle and enable the under voltage protection of
the output voltages.
Figure 3 shows a typical start up interval for uP6161 where
the RT/DIS pin has been released from a grounded (system
shutdown) state. Note the LDO output voltage (LVO)
starts ramping up only after the PWM output voltage
(SVO) is within regulation.
RT/DIS
(1V/Div)
SVO
(0.5V/Div)
LVO
(0.5V/Div)
ramping up to 5VDD. Another softstart is initiated after SS
ramps up to 5VDD. The hiccup period is about 8ms. Figure
4 shows the start up interval where VIN does not present
initially.
SVO
(0.5V/Div)
V IN
(5V/Div)
LVO
(0.5V/Div)
LGATE
(10V/Div)
Time (5ms/Div)
Figure 4. Softstart where VIN does not Present Initially.
Output Voltage Selection
The output voltage can be programmed to any level between
the 0.8V internal reference, up to the 80% of VIN supply.
The lower limitation of output voltage is caused by the
internal reference. The upper limitation of the output voltage
is caused by the maximum available duty cycle (80%
typical). This is to leave enough time for overcurrent
detection. Output voltage out of this range is not allowed.
A voltage divider sets the output voltage (refer to the Typical
Application Circuit on page 1 for detail). In real applications,
choose R2 in 100Ω ~ 10kΩ range and choose appropriate
R1 according to the desired output voltage.
VOUT = VREF ×
R1 + R2
R1 + R2
= 0.8 V ×
R2
R2
Overcurrent Protection (OCP)
PHASE
(10V/Div)
Time (5ms/Div)
Figure 3. Softstart Behavior.
Power Input Detection
The uP6161 detects PHASE voltage for the present of power
input when the UGATE turns on the first time. If the PHASE
voltage does not exceed 2.0V when the UGATE turns on,
the uP6161 asserts that power input in not ready and stops
the softstart cycle. However, the internal SS continues
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
The uP6161 detects voltage drop across the lower MOSFET
(VPHASE) for overcurrent protection when it is turned on. If
VPHASE is lower than the user-programmable voltage VOCP,
the uP6161 asserts OCP and shuts down the converter.
The OCP level can be calculated according the onresistance of the lower MOSFET used.
IOCP = −
VOCP
RDS(ON)
(A)
Connecting a resistance from LGATE to GND selects the
6
www.datasheet4u.com
Preliminary
uP6161
Functional Description
appropriate VOCP as shown in Table 1. Also shown in Table
1 is OCP level if a lower MOSFET with 10mΩ RDS(ON) is
used.
When programming the OCP level, take into consideration
the conditions that affect RDS(ON) of the lower MOSFET,
including operation junction temperature, gate driving voltage
and distribution. Consider the RDS(ON) at maximum operation
temperature and lowest gate driving voltage.
Table 1. OCP Level Selection
ROCP (Ω)
open
42k
24k
10k
VOCP (mV)
-375
-300
-225
-150
IOCP (A)
37.5
25
22.5
15
Another factor should taken into consideration is the ripple
of the inductor current. The current near the valley of the
ripple current is used for OCP, resulting the averaged OCP
level a little higher than the calculated value.
Output Under Voltage Protection of Linear Regulator
The LDRV and LFB voltages are monitored during both
softstart and normal operation for output under voltage
protection. The uP6161 asserts UVP if the error amplifier
saturates, LDRV goes to ceiling high and LFB voltage is
lower than 0.6V for 10us. This demands VCC12 > (VOUT +
VTH + 1V) where VTH is the threshold voltage of the external
N-Channel MOSFET. This is to ensure that the output
voltage can follow the softstart signal and will not saturate
the error amplifier. That means a low threshold voltage
MOSFET is required for low VCC12 applications. This also
demands that VIN2 should be ready before the soft start
cycle is initiated.
The uP6161 disables the output voltages upon the triggering
of UVP. The uP6161 repeats the softstart cycle if the output
under voltage is not removed.
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
7
www.datasheet4u.com
uP6161
Preliminary
Absolute Maximum Rating
Supply Input Voltage, VCC12 (Note 1) -------------------------------------------------------------------------------------------- -0.3V to +15V
PHASE to GND
DC ------------------------------------------------------------------------------------------------------------------------------------- -1V to 15V
< 200ns ---------------------------------------------------------------------------------------------------------------------------- -3V to 30V
BOOT to PHASE ---------------------------------------------------------------------------------------------------------------------------- -0.3V to +15V
UGATE to PHASE ------------------------------------------------------------------------------------------------ -0.3V to (BOOT - PHASE +0.3V)
PVCC9, VCC9, LDRV ----------------------------------------------------------------------------------------------------- -0.3V to VCC12 + 0.3V
LGATE ------------------------------------------------------------------------------------------------------------------------ -0.3V to + (PVCC9 + 0.3V)
Other Pins -------------------------------------------------------------------------------------------------------------------------------------- -0.3V to +6V
Storage Temperature Range ------------------------------------------------------------------------------------------------------------- -65OC to +150OC
Junction Temperature ------------------------------------------------------------------------------------------------------------------------------------ 150OC
Lead Temperature (Soldering, 10 sec) ------------------------------------------------------------------------------------------------------------ 260OC
ESD Rating (Note 2)
HBM (Human Body Mode) --------------------------------------------------------------------------------------------------------------------- 2kV
MM (Machine Mode) ----------------------------------------------------------------------------------------------------------------------------- 200V
Thermal Information
Package Thermal Resistance (Note 3)
θJA SOP-14 ------------------------------------------------------------------------------------------------------------------------------ 120°C/W
θJC QFN3x3-16 ----------------------------------------------------------------------------------------------------------------------------- 5OC/W
θJA QFN3x3-16 ---------------------------------------------------------------------------------------------------------------------------- 68OC/W
Power Dissipation, PD @ TA = 25°C
SOP-14 ----------------------------------------------------------------------------------------------------------------------------------------------- 0.83W
QFN3x3-16 ------------------------------------------------------------------------------------------------------------------------------------------ 1.47W
Recommended Operation Conditions
Operating Junction Temperature Range (Note 4) ------------------------------------------------------------------------ -40°C to +125°C
Operating Ambient Temperature Range -------------------------------------------------------------------------------------- -40°C to +85°C
Supply Input Voltage, VCC12 ----------------------------------------------------------------------------------------------------------- +10.8V to 13.2V
Electrical Characteristics
(VCC12 = 12V, TA = 25OC, unless otherwise specified)
Parameter
Symbol Test Conditions
Min
Typ
Max
Units
Supply Input
Supply Voltage
V C C 12
Supply Current
ICC12
Quiescent Supply Current
ICC12_Q
10.8
--
13.2
V
UGATE and LGATE Open; VCC12 = 12V,
Switching
--
4
--
mA
VFB = VREF + 0.1V, No Switching
--
3
--
mA
13.2
V
VIN1
3.0
VCC12 POR Threshold
VCC12RTH
--
8.7
--
V
PVCC9 POR Threshold
VVCC9RTH PVCC9 = VCC9 rising
--
7.5
8
V
POR Hysteresis
VCC9HYS
PVCC9 = VCC9 falling
--
0.8
--
V
Power Input Voltage
Pow er On Reset
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
8
www.datasheet4u.com
uP6161
Preliminary
Electrical Characteristics
Parameter
Symbol
Test Conditions
Min
Typ
Max
Units
--
9.0
--
V
540
620
700
kHz
--
4
--
V
--
6.8
--
ms
P V C C 9 LD O
PVCC9 Output Voltage
PVC C 9
V C C 12 = 1 2 V
Oscillator and Soft Start
Switching Frequency
fOSC
Sawtooth Amplitude
ΔVOSC
Soft Start Interval
TSS
RRT = 45.3kΩ
fOSC = 620kHz
Reference Voltage
Reference Voltage for PWM
VREF
0.788
0.8
0.812
V
Reference Voltage for LDO
VREF
0.784
0.8
0.816
V
Error Amplifier for Buck Controller
Open Loop DC Gain
Gain-Bandwidth Product
Slew Rate
AO
Guaranteed by Design
55
70
--
dB
GBWP
Guaranteed by Design
--
10
--
MHz
SR
Guaranteed by Design
4
6
--
V/us
COMP High Output Voltage
VCOMP_H
--
4.7
--
V
COMP Low Output Voltage
VCOMP_L
--
0.6
--
V
COMP High Source Current
ICOMP_H
--
-2.8
--
mA
Undervoltage Level (VFB/VREF)
VUVP
70
75
80
%
Buck Controller Gate Drivers
UGATE Source Current
IUG_SRC
PVCC = 9V, VBOOT - VUG = 8V
--
-1.5
--
A
UGATE Sink Output Impedance
RUG_SNK
PVCC = 9V, IUG = 100mA
--
2
4
Ω
LGATE Source Current
ILG_SRC
PVCC = 9V, VLG = 1V
--
-1.5
--
A
LGATE Sink Output Impedance
RLG_SNK
PVCC = 9V, ILG = 100mA
--
2
4
Ω
70
75
80
%
Maximum Duty Cycle
Linear-Regulator Controller
AO
Guaranteed by Design
55
70
--
dB
GBWP
Guaranteed by Design
--
2
--
MHz
Slew Rate
SR
Guaranteed by Design
2
4
--
V/us
FB Bias Current
IFB
VFB = 0.8V
--
0.01
1
uA
LDRV High Output Voltage
VLDRV_H
P V C C = 9V
--
8.5
9.0
V
LDRV Low Output Voltage
VLDRV_L
P V C C = 9V
--
0.0
0.5
V
LDRV High Source Current
ILDRV_H
5
--
--
mA
LDRV Low Sink Current
ILDRV_L
5
--
--
mA
Undervoltage Level (VLFB/VREF)
VUVP
70
75
80
%
Open Loop DC Gain
Gain-Bandwidth Product
Percent of Nominal
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
9
www.datasheet4u.com
uP6161
Preliminary
Electrical Characteristics
Parameter
Symbol
Test Conditions
Min
Typ
Max
Units
--
-375
--
mV
0.3
0.4
0.5
V
Protection
Over Current Threshold
VPHASE
Enable Threshold
VRT/DIS
RLGATE = open
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. Devices are ESD sensitive. Handling precaution recommended.
Note 3. θJA is measured in the natural convection at TA = 25°C on a low effective thermal conductivity test board of
JEDEC 51-3 thermal measurement standard.
Note 4. The device is not guaranteed to function outside its operating conditions.
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
10
www.datasheet4u.com
uP6161
Preliminary
Typical Operation Characteristics
Turn On Waveforms
Power On Waveforms
SVOUT
(0.5V/Div)
VCC12
(5V/Div)
LVOUT
(0.5V/Div)
PVCC9
(5V/Div)
SVOUT
(0.5V/Div)
RT/DIS
(0.5V/Div)
LVOUT
(0.5V/Div)
PHASE
(10V/Div)
2.5ms/Div
5ms/Div
Gate Waveforms
Gate Waveforms
UGATE
(5V/Div)
UGATE
(5V/Div)
PHASE
(5V/Div)
LGATE
(5V/Div)
PHASE
(5V/Div)
LGATE
(5V/Div)
UGATE-PHASE
(5V/Div)
UGATE-PHASE
(5V/Div)
25ns/Div
25ns/Div
Over Current Protection
Trun Off Waveforms
RT/DIS
(1V/Div)
SVOUT
(0.5V/Div)
LDRV
(2V/Div)
PHASE
(10V/Div)
PHASE
(10V/Div)
IOUT
(10A/Div)
10ms/Div
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
5us/Div
11
www.datasheet4u.com
uP6161
Preliminary
Typical Operation Characteristics
PVCC9 Voltage vs. VCC12 Voltage
Switching Frequency vs. RRT
10
1000
Switching Frequency (kHz)
PVCC9 Voltage (V)
9.5
9
8.5
8
7.5
100
7
8
10
12
1000
PVCC9 Voltage vs. Temperature
DC/DC Output Voltage vs. Temperature
DC/DC Output Voltage Variation (%)
9.06
9.05
9.04
9.03
9.02
9.01
9
-50
0
50
100
0.5
0.2
-0.1
-0.4
-0.7
-1
-50
150
O
0
50
100
150
O
Junction Temperature ( C)
VCC12 = 12V
Junction Temperature ( C)
Switching Frequency vs. Temperature
LDO Output Voltage vs. Temperature
2
0.5
LDO Output Voltage Variation (%)
Switching Frequency Variation (%)
100
RRT (kΩ)
9.07
PVCC9 Output Voltage (V)
10
14
VCC12 Voltage (V)
1
0
-1
-2
-3
-4
-50
0
50
100
O
Junction Temperature ( C)
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
150
0.3
0.1
-0.1
-0.3
-0.5
-0.7
-0.9
-1.1
-1.3
-1.5
-50
0
50
100
150
O
Junction Temperature ( C)
12
www.datasheet4u.com
Preliminary
uP6161
Application Information
This page is intentionally left blank and will be updated when the silicon data is available.
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
13
www.datasheet4u.com
uP6161
Preliminary
Package Information
SOP-14 Package
0.76 REF
1.27 REF
1.85 REF
8.50 - 8.75
5.80 - 6.20
3.80 - 4.00
4.00 MIN
8.00 MIN
6.15 REF
1.27 BSC
0.32 - 0.52
Recommended Solder Pad Layout
1.45 - 1.60
0.20 BSC
0.18 - 0.25
1.75 MAX
0.10 - 0.25
0.41 - 0.89
7.62 BSC
Note
1.Package Outline Unit Description:
BSC: Basic. Represents theoretical exact dimension or dimension target
MIN: Minimum dimension specified.
MAX: Maximum dimension specified.
REF: Reference. Represents dimension for reference use only. This value is not a device specification.
TYP. Typical. Provided as a general value. This value is not a device specification.
2.Dimensions in Millimeters.
3.Drawing not to scale.
4.These dimensions no not include mold flash or protrusions. Mold flash or protrusions shell not exceed 0.15mm.
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
14
www.datasheet4u.com
uP6161
Preliminary
Package Information
QFN3x3 - 16L Package
0.35 - 0.45
1.50 - 1.75
9
13
1.50 - 1.75
2.90 - 3.10
Pin 1 mark
(Note 6)
5
1
2.90 - 3.10
0.18 - 0.30
0.50 BSC
Bottom View - Exposed Pad
0.80 - 1.00
3.45 - 3.55
1.60 - 1.70
0.00 - 0.05
2.10 - 2.20
0.20 - REF
0.20 - 0.30
0.50 BSC
Recommended Solder Pitch and Dimensions
Note
1.Package Outline Unit Description:
BSC: Basic. Represents theoretical exact dimension or dimension target
MIN: Minimum dimension specified.
MAX: Maximum dimension specified.
REF: Reference. Represents dimension for reference use only. This value is not a device specification.
TYP. Typical. Provided as a general value. This value is not a device specification.
2.Dimensions in Millimeters.
3.Drawing not to scale.
4.These dimensions no not include mold flash or protrusions. Mold flash or protrusions shell not exceed 0.15mm.
uPI Semiconductor Corp., http://www.upi-semi.com
Rev. P00, File Name: uP6161-DS-P0001
15