HTC TJ2996DP

DDR Termination Regulator
TJ2996
FEATURES
z
z
z
z
z
z
z
z
Source and sink current
Low output voltage offset
No external resistors required
Linear topology
Suspend to Ram (STR) functionality
Low external component count
Thermal Shutdown
Available in SOP8, SOP8-PP Packages
SOP8 / SOP8-PP PKG
ORDERING INFORMATION
APPLICATION
Device
Package
TJ2996D
SOP8
TJ2996DP
SOP8-PP
z DDR-I, DDR-II and DDR-Ⅲ Termination Voltage
z SSTL-2 and SSTL-3 Termination
z HSTL Termination
DESCRIPSION
The TJ2996 linear regulator is designed to meet the JEDEC SSTL-2 and SSTL-3 specifications for
termination of DDR-SDRAM. The device contains a high-speed operational amplifier to provide excellent
response to load transients. The output stage prevents shoot through while delivering 1.5A continuous
current and transient peaks up to 3A in the application as required for DDR-SDRAM termination. The
TJ2996 also incorporates a VSENSE pin to provide superior load regulation and a VREF output as a reference
) pin
for the chipset and DIMMs. An additional feature found on the TJ2996 is an active low shutdown (
is pulled low the VTT output will tri-state
that provides Suspend To RAM (STR) functionality. When
providing a high impedance output, but, VREF will remain active. A power savings advantage can be obtained
in this mode through lower quiescent current.
Absolute Maximum Ratings
CHARACTERISTIC
SYMBOL
MIN.
MAX.
UNIT
Supply Voltage to GND
PVIN
AVIN
VDDQ
-0.3
-0.3
-0.3
6.0
6.0
6.0
V
Lead Temperature (Soldering, 10 sec)
TSOL
260
℃
Storage Temperature Range
TSTG
-65
150
℃
Operating Junction Temperature Range
TJOPR
-40
125
℃
SYMBOL
MIN.
MAX.
UNIT
AVIN
2.3
5.5
V
PVIN & SD Input
0
AVIN
V
Recommended Operation Range
CHARACTERISTIC
AVIN to GND
PVIN & SDVIN to GND
Ordering Information
Package
Order No.
Description
Package Marking
Supplied As
SOP8
TJ2996D
DDR Termination Regulator
TJ2996
Reel
SOP8-PP
TJ2996DP
DDR Termination Regulator
TJ2996
Reel
Jul. 2010 - Rev. 1.5.3
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HTC
DDR Termination Regulator
TJ2996
PIN CONFIGURATION
GND 1
GND 1
8 VTT
SD 2
SD 2
7 PVIN
8 VTT
Exposed
7 PVIN
Thermal
VSENSE 3
VSENSE 3
6 AVIN
VREF 4
PAD
VREF 4
5 VDDQ
SOP8
6 AVIN
5 VDDQ
SOP8-PP
PIN DESCRIPTION
Pin No.
Pin Name
1
GND
2
Pin Function
Ground
Enable
3
VSENSE
4
VREF
Buffered Internal Reference Voltage of VDDQ/2
5
VDDQ
Input for Internal Reference Equal to VDDQ/2
6
AVIN
Analog Input Pin
7
PVIN
Power Input Pin
8
VTT
Output Voltage for Connection to Termination Resistors
Exposed Thermal PAD
Feedback Pin for Regulating VTT
Exposed Thermal Connection. Connect to Ground. (SOP8-PP Only)
TYPICAL APPLICATION
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HTC
DDR Termination Regulator
TJ2996
ELECTRICAL CHARACTERISTICS (1)
Specifications with standard typeface are for TJ = 25˚. Unless otherwise specified, AVIN = PVIN = 2.5V, VDDQ = 2.5V
(1), (2), (3)
(1), (2), (3)
for DDRⅡ. AVIN = 2.5V, PVIN = VDDQ = 1.5V
for DDRⅢ.
DDRⅠ, AVIN = 2.5V, PVIN = VDDQ = 1.8V
PARAMETER
SYMBOL
TEST CONDITION
(1), (2), (3), (4)
MIN.
TYP.
MAX.
UNIT
VREF Voltage
VREF
VDDQ = 2.5V
1.21
1.25
1.29
V
VREF Voltage
VREF
VDDQ = 1.8V
0.86
0.90
0.94
V
VREF Voltage
VREF
VDDQ = 1.5V
0.71
0.75
0.79
V
VTT
IOUT = 0 A
VDDQ = 2.5V
IOUT = ± 1.5 A (7)
VDDQ = 2.5V
1.21
1.25
1.29
1.21
1.25
1.29
0.86
0.90
0.94
0.86
0.90
0.94
0.71
0.75
0.79
0.71
0.75
0.79
-40
-40
-40
-40
0
0
0
0
40
40
40
40
mV
-
250
2000
uA
-
100
-
kΩ
VTT Output Voltage
VTT Output Voltage
VTT Output Voltage
VTT
VTT
IOUT = 0 A
VDDQ = 1.8V
IOUT = ± 0.9 A (7)
VDDQ = 1.8V
IOUT = 0 A
VDDQ = 1.5V
IOUT = ± 0.5 A (7)
VDDQ = 1.5V
IOUT = 0 A
VTT Output Voltage Offset
VOSVTT
IOUT = ± 0.5 A (7)
IOUT = ± 0.9 A (7)
IOUT = ± 1.5 A (7)
Quiescent Current (5)
VDDQ Input Impedance
Quiescent Current in Shutdown(5)
IQ
IOUT = 0A
ZVDDQ
V
V
V
ISD
= 0V
200
2000
uA
Shutdown Leakage Current
IQ_SD
= 0V
0.1
0.5
uA
Minimum Enable High Level
VIH
1.9
-
-
V
Maximum Enable Low Level
VIL
-
-
0.6
V
VTT Leakage Current in Shutdown
IV
1
10
uA
= 0V,
VTT = 1.25V
(8)
VSENSE Input Current
ISENSE
-
-
0.1
uA
Thermal Shutdown(6)
TSD
-
165
-
℃
Note 1. Absolute maximum ratings indicate limits beyond which damage to the device may occur. Operating range indicates conditions
for which the device is intended to be functional, but does not guarantee specific performance limits. For guaranteed
specifications and test conditions see Electrical Characteristics. The guaranteed specifications apply only for the test conditions
listed. Some performance characteristics may degrade when the device is not operated under the listed test conditions.
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for
HTC
DDR Termination Regulator
TJ2996
Note 2. At elevated temperatures, devices must be derated based on thermal resistance. The device in the SOP8 package must be
derated at θJA
= 165˚ C/W junction to ambient with no heat sink.
Note 3. Limits are 100% production tested at 25˚C. Limits over the operating temperature range are guaranteed through correlation.
Note 4. VIN is defined as VIN = AVIN = PVIN
Note 5. Quiescent current defined as the current flow into AVIN.
Note 6. The maximum allowable power dissipation is a function of the maximum junction temperature, TJ(MAX), the junction to ambient
thermal resistance, θJA, and the ambient temperature, TA. Exceeding the maximum allowable power dissipation will cause
excessive die temperature and the regulator will go into thermal shutdown.
Note 7. VTT load regulation is tested by using a 10 ms current pulse and measuring VTT.
Note 8. In the case of AVIN > 2.5V, minimum enable high level is AVIN * 0.7.
TYPICAL OPERATING CHARACTERISTICS
AVIN : 2.0V/div, VDDQ/PVIN : 1.0V/div, VREF : 500mV/div, VTT : 500mV/div, Time : 10ms/div
Start Up
Shut Down
AVIN : 2.0V/div, VDDQ/PVIN : 2.0V/div, EN : 2.0V/div, VTT : 500mV/div, Time : 10ms/div
Start Up by EN
Jul. 2010 - Rev. 1.5.3
AVIN : 2.0V/div, VDDQ/PVIN : 1.0V/div, VREF : 500mV/div, VTT : 500mV/div, Time : 10ms/div
AVIN : 2.0V/div, VDDQ/PVIN : 2.0V/div, EN : 2.0V/div, VTT : 500mV/div, Time : 10ms/div
Shut Down by EN
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HTC
DDR Termination Regulator
TJ2996
AVIN : 2.0V/div, VDDQ/PVIN : 2.0V/div, VTT : 500mV/div, IOUT : 1A/div, Time : 10ms/div
Load (0A → 1A)
AVIN : 2.0V/div, VDDQ/PVIN : 2.0V/div, VTT : 500mV/div, IOUT : 1A/div, Time : 10ms/div
Load (1A → 0A)
VDDQ = 1.8V
AVIN vs. Quiescent Current
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HTC
DDR Termination Regulator
TJ2996
DESCRIPTION
The TJ2996 is a linear bus termination regulator designed to meet the JEDEC requirements of SSTL-2.
The output, VTT is capable of sinking and sourcing current while regulating the output voltage equal to
VDDQ / 2. The output stage has been designed to maintain excellent load regulation while preventing
shoot through. The TJ2996 also incorporates two distinct power rails that separate the analog circuitry
from the power output stage. This allows a split rail approach to be utilized to decrease internal power
dissipation. It also permits the TJ2996 to provide a termination solution for the next generation of DDRSDRAM memory (DDRII). The TJ2996 can also be used to provide a termination voltage for other logic
schemes such as SSTL-3 or HSTL.
Series Stub Termination Logic (SSTL) was created to improve signal integrity of the data transmission
across the memory bus. This termination scheme is essential to prevent data error from signal
reflections while transmitting at high frequencies encountered with DDR-SDRAM. The most common
form of termination is Class II single parallel termination. This involves one RS series resistor from the
chipset to the memory and one RT termination resistor. Typical values for RS and RT are 25 Ohms,
although these can be changed to scale the current requirements from the TJ2996. This implementation
can be seen below in Figure 1.
FIGURE 1. SSTL-Termination Scheme
PIN DESCRIPTION
AVIN AND PVIN
AVIN and PVIN are the input supply pins for the TJ2996. AVIN is used to supply all the internal control
circuitry. PVIN, however, is used exclusively to provide the rail voltage for the output stage used to
create VTT. These pins have the capability to work off separate supplies depending on the application.
Higher voltages on PVIN will increase the maximum continuous output current because of output RDSON
limitations at voltages close to VTT. The disadvantage of high values of PVIN is that the internal power
loss will also increase, thermally limiting the design. For SSTL-2 applications, a good compromise
would be to connect the AVIN and PVIN directly together at 2.5V. This eliminates the need for bypassing
the two supply pins separately. The only limitation on input voltage selection is that PVIN must be equal
to or lower than AVIN. It is recommended to connect PVIN to voltage rails equal to or less than 3.3V to
prevent the thermal limit from tripping because of excessive internal power dissipation. If the junction
temperature exceeds the thermal shutdown than the part will enter a shutdown state identical to the
manual shutdown where VTT is tri-stated and VREF remains active.
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HTC
DDR Termination Regulator
TJ2996
VDDQ
VDDQ is the input used to create the internal reference voltage for regulating VTT. The reference
voltage is generated from a resistor divider of two internal 50kΩ resistors. This guarantees that VTT will
track VDDQ / 2 precisely. The optimal implementation of VDDQ is as a remote sense. This can be
achieved by connecting VDDQ directly to the 2.5V rail at the DIMM instead of AVIN and PVIN. This
ensures that the reference voltage tracks the DDR memory rails precisely without a large voltage drop
from the power lines. For SSTL-2 applications VDDQ will be a 2.5V signal, which will create a 1.25V
termination voltage at VTT (See Electrical Characteristics Table for exact values of VTT over
temperature)
VSENSE
The purpose of the sense pin is to provide improved remote load regulation. In most motherboard
applications the termination resistors will connect to VTT in a long plane. If the output voltage was
regulated only at the output of the TJ2996 then the long trace will cause a significant IR drop resulting in
a termination voltage lower at one end of the bus than the other. The VSENSE pin can be used to improve
this performance, by connecting it to the middle of the bus. This will provide a better distribution across
the entire termination bus. If remote load regulation is not used then the VSENSE pin must still be
connected to VTT. Care should be taken when a long VSENSE trace is implemented in close proximity to
the memory. Noise pickup in the VSENSE trace can cause problems with precise regulation of VTT. A
small 0.1uF ceramic capacitor placed next to the VSENSE pin can help filter any high frequency signals and
preventing errors.
SHUTDOWN
The TJ2996 contains an active low shutdown pin that can be used to tri-state VTT. During shutdown
VTT should not be exposed to voltages that exceed AVIN. With the shutdown pin asserted low the
quiescent current of the TJ2996 will drop, however, VDDQ will always maintain its constant impedance of
100kΩ for generating the internal reference. Therefore to calculate the total power loss in shutdown
both currents need to be considered. For more information refer to the Thermal Dissipation section.
VREF
VREF provides the buffered output of the internal reference voltage VDDQ / 2. This output should be
used to provide the reference voltage for the Northbridge chipset and memory. Since these inputs are
typically extremely high impedance, there should be little current drawn from VREF. For improved
performance, an output bypass capacitor can be used, located close to the pin, to help with noise. A
ceramic capacitor in the range of 0.1 µF to 0.01 µF is recommended. This output remains active during
the shutdown state for the suspend to RAM functionality.
VTT
VTT is the regulated output that is used to terminate the bus resistors. It is capable of sinking and
sourcing current while regulating the output precisely to VDDQ / 2. The TJ2996 is designed to handle
peak transient currents of up to ± 3A with a fast transient response. If a transient is expected to last
above the maximum continuous current rating for a significant amount of time then the output capacitor
should be sized large enough to prevent an excessive voltage drop. Despite the fact that the TJ2996 is
designed to handle large transient output currents it is not capable of handling these for long durations,
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HTC
DDR Termination Regulator
TJ2996
under all conditions. The reason for this is the standard packages are not able to thermally dissipate the
heat as a result of the internal power loss. If large currents are required for longer durations, then care
should be taken to ensure that the maximum junction temperature is not exceeded. Proper thermal
derating should always be used (please refer to the Thermal Dissipation section). If the junction
temperature exceeds the thermal shutdown point than VTT will tri-state until the part returns below the
hysteretic trip-point.
THERMAL DISSIPATION
Since the TJ2996 is a linear regulator any current flow from VTT will result in internal power dissipation
generating heat. To prevent damaging the part from exceeding the maximum allowable junction
temperature, care should be taken to derate the part dependent on the maximum expected ambient
temperature and power dissipation. The maximum allowable internal temperature rise, TRmax can be
calculated given the maximum ambient temperature, TAmax of the application and the maximum allowable
junction temperature, TJmax.
TRmax = TJmax − TAmax
From this equation, the maximum allowable power dissipation, PDmax of the part can be
calculated:
PDmax = TRmax / θ JA
The maximum allowable value for junction-to-ambient thermal resistance, θJA, can be calculated using
the formula:
θJA = TRmax / PD = (TJmax – TAmax) / PD
The θJA of the TJ2996 will be dependent on several variables: the package used; the thickness of
copper; the number of vias and the airflow. For instance, the θJA of the SOP8 is 165°C/W with the
package mounted to a standard 8x4 2-layer board with 1oz. copper, no airflow, and 0.5W dissipation at
room temperature. This value can be reduced to 152°C/W by changing to a 3x4 board with 2 oz. copper
that is the JEDEC standard.
Additional improvements can be made by the judicious use of vias to connect the part and
dissipate heat to an internal ground plane. Using larger traces and more copper on the top side of
the board can also help.
With careful layout it is possible to reduce the θJA further than the nominal
values. Additional improvements in lowering the θ JA can also be achieved with a constant airflow
across the package.
Optimizing the θJA and placing the TJ2996 in a section of a board exposed to lower ambient
temperature allows the part to operate with higher power dissipation. The internal power dissipation
can be calculated by summing the three main sources of loss: output current at VTT, either sinking or
sourcing, and quiescent current at AVIN and VDDQ. During the active state (when shutdown is not held
low) the total internal power dissipation can be calculated from the following equations:
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HTC
DDR Termination Regulator
PD =
PAVIN
+
TJ2996
PVDDQ + PVTT
Where, PAVIN =
PVDDQ
=
IAVIN
x
VAVIN
VVDDQ
x
IVDDQ
=
VVDDQ2
x
RVDDQ
To calculate the maximum power dissipation at VTT both conditions at VTT need to be examined,
sinking and sourcing current. Although only one equation will add into the total, VTT cannot source and
sink current simultaneously.
PVTT = VVTT x ILOAD (Sinking)
or
PVTT = ( VPVIN - VVTT) x ILOAD (Sourcing)
The power dissipation of the TJ2996 can also be calculated during the shutdown state. During this
condition the output VTT will tri-state, therefore that term in the power equation will disappear as it
cannot sink or source any current (leakage is negligible). The only losses during shutdown will be
the reduced quiescent current at AVIN and the constant impedance that is seen at the VDDQ pin.
PD = PAVIN + PVDDQ ,
Where, PAVIN = IAVIN x VAVIN
PVDDQ
Jul. 2010 - Rev. 1.5.3
= VVDDQ
x IVDDQ
= VVDDQ2
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x RVDDQ
HTC
DDR Termination Regulator
TJ2996
TYPICAL APPLICATION INFORMATION
Several different application circuits have been shown in Figure 2 through Figure 11 to illustrate some
of the options that are possible in configuring the TJ2996.
SSTL-2 APPLICATIONS
For the majority of applications that implement the SSTL-2 termination scheme it is recommended to
connect all the input rails to the 2.5V rail. This provides an optimal trade-off between power dissipation
and component count and selection. An example of this circuit can be seen in Figure 2.
FIGURE 2. Recommended SSTL-2 Implementation
If power dissipation or efficiency is a major concern then the TJ2996 has the ability to operate on split
power rails. The output stage (PVIN) can be operated on a lower rail such as 1.8V and the analog
circuitry (AVIN) can be connected to a higher rail such as 2.5V, 3.3V or 5V. This allows the internal
power dissipation to be lowered when sourcing current from VTT. The disadvantage of this circuit is that
the maximum continuous current is reduced because of the lower rail voltage, although it is adequate for
all motherboard SSTL-2 applications. Increasing the output capacitance can also help if periods of large
load transients will be encountered.
FIGURE 3. Lower Power Dissipation SSTL-2 Implementation
The third option for SSTL-2 applications in the situation that a 1.8V rail is not available and it is not
desirable to use 2.5V is to connect the TJ2996 power rail to 3.3V. In this situation AVIN will be limited to
operation on the 3.3V or 5V rail as PVIN can never exceed AVIN. This configuration has the ability to
provide the maximum continuous output current at the downside of higher thermal dissipation. Care
should be taken to prevent the TJ2996 from experiencing large current levels which cause the junction
temperature to exceed the maximum. Because of this risk it is not recommended to supply the output
stage with a voltage higher than a nominal 3.3V rail.
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DDR Termination Regulator
TJ2996
FIGURE 4. SSTL-2 Implementation with higher voltage rails
DDR-II APPLICATIONS
With the separate VDDQ pin and an internal resistor divider it is possible to use the TJ2996 in
applications utilizing DDR-II memory. Figure 3 and Figure 4 show several implementations of
recommended circuits. Figure 3 shows the recommended circuit configuration for DDR-II applications.
The output stage is connected to the 1.8V rail and the AVIN pin can be connected to either a 3.3V or 5V
rail.
FIGURE 5. Recommended DDR-II Termination
If it is not desirable to use the 1.8V rail it is possible to connect the output stage to a 3.3V rail. Care
should be taken to do not exceed the maximum junction temperature as the thermal dissipation
increases with lower VTT output voltages. For this reason it is not recommended to power PVIN off a rail
higher than the nominal 3.3V. The advantage of this configuration is that it has the ability to source and
sink a higher maximum continuous current.
FIGURE 6. DDR-II Termination with higher voltage rails
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DDR Termination Regulator
TJ2996
LEVEL SHIFTING
If standards other than SSTL-2 are required, such as SSTL-3, it may be necessary to use a different
scaling factor than 0.5 times VDDQ for regulating the output voltage. Several options are available to
scale the output to any voltage required. One method is to level shift the output by using feedback
resistors from VTT to the VSENSE pin. This has been illustrated in Figures 7 and 8. Figure 7 shows how
to use two resistors to level shift VTT above the internal reference voltage of VDDQ / 2. To calculate the
exact voltage at VTT the following equation can be used
VTT = VDDQ / 2 ( 1 + R1 / R2 )
FIGURE 7. Increasing VTT by Level Shifting
Conversely, the R2 resistor can be placed between VSENSE and VDDQ to shift the VTT output lower than
the internal reference voltage of VDDQ / 2. The equations relating VTT and the resistors can be seen
below:
VTT = VDDQ / 2 (1 - R1 / R2)
FIGURE 8. Decreasing VTT by Level Shifting
HSTL APPLICATIONS
The TJ2996 can be easily adapted for HSTL applications by connecting VDDQ to the 1.5V rail. This will
produce a VTT and VREF voltage of approximately 0.75V for the termination resistors. It is possible to
connect PVIN to higher than a 2.5V rail. Care should be taken to do not exceed the maximum junction
temperature as the thermal dissipation increases with lower VTT output voltages (For more information,
refer to the Thermal Dissipation section.). The advantage of this configuration is that it has the ability to
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HTC
DDR Termination Regulator
TJ2996
source and sink a higher maximum continuous current. PVIN can be also connected to a 1.8V rail and it
has a limitation of maximum continuous current. PVIN should be connected to a voltage higher than a
1.5V rail.
FIGURE 9. HSTL Application
QDR APPLICATIONS
Quad data rate (QDR) applications utilize multiple channels for improved memory performance.
However, this increase in bus lines has the effect of increasing the current levels required for termination.
The recommended approach in terminating multiple channels is to use a dedicated TJ2996 for each
channel. This simplifies layout and reduces the internal power dissipation for each regulator. Separate
VREF signals can be used for each DIMM bank from the corresponding regulator with the chipset
reference provided by a local resistor divider or one of the TJ2996 signals. Because VREF and VTT are
expected to track and the part to part variations are minor, there should be little difference between the
reference signals of each TJ2996.
FIGURE 10. Typical SSTL-2 Application Circuit
OUTPUT CAPACITOR SELECTION
For applications utilizing the TJ2996 to terminate SSTL-2 I/O signals the typical application circuit
shown in Figure 8 can be implemented. This circuit permits termination in a minimum amount of board
space and component count. Capacitor selection can be varied depending on the number of lines
terminated and the maximum load transient. However, with motherboards and other applications where
VTT is distributed across a long plane it is advisable to use multiple bulk capacitors and addition to high
frequency decoupling. Figure 9 shown below depicts an example circuit where 2 bulk output capacitors
could be situated at both ends of the VTT plane for optimal placement. Large aluminum electrolytic
capacitors are used for their low ESR and low cost.
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DDR Termination Regulator
TJ2996
FIGURE 11. Typical SSTL-2 Application Circuit for Motherboards
In most PC applications an extensive amount of decoupling is required because of the long
interconnects encountered with the DDR-SDRAM DIMMs mounted on modules. As a result bulk
aluminum electrolytic capacitors in the range of 1000uF are typically used.
PCB LAYOUT CONSIDERATIONS
1. The input capacitor for the power rail should be placed as close as possible to the PVIN pin.
2. VSENSE should be connected to the VTT termination bus at the point where regulation is required. For
mother- board applications an ideal location would be at the center of the termination bus.
3. VDDQ can be connected remotely to the VDDQ rail input at either the DIMM or the Chipset. This provides
the most accurate point for creating the reference voltage.
4. For improved thermal performance excessive top side copper should be used to dissipate heat from
the package. Numerous vias from the ground connection to the internal ground plane will help.
Additionally these can be located underneath the package if manufacturing standards permit.
5. Care should be taken when routing the VSENSE trace to avoid noise pickup from switching I/O signals. A
0.1uF ceramic capacitor located close to the SENSE can also be used to filter any unwanted high
frequency signal. This can be an issue especially if long SENSE traces are used.
6. VREF should be bypassed with a 0.01µF or 0.1µF ceramic capacitor for improved performance. This
capacitor should be located as close as possible to the VREF pin
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