Fairchild FAN5066 Ultra low voltage synchronous dc-dc controller Datasheet

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FAN5066
Ultra Low Voltage Synchronous DC-DC Controller
Features
Description
•
•
•
•
•
•
•
•
The FAN5066 is a synchronous mode DC-DC controller IC
which provides an adjustable output voltage for ultra-low
voltage applications, down to 400mV. The FAN5066 uses a
high level of integration to deliver load currents in excess of
19A from a 5V source with minimal external circuitry.
Synchronous-mode operation offers optimum efficiency over
the entire output voltage range, and the internal oscillator
can be programmed from 80KHz to 1MHz for additional
flexibility in choosing external components. The FAN5066
also offers integrated functions including a four-bit
DAC-controlled reference, Power Good, Output Enable,
over-voltage protection and current limiting.
Output adjustable from 400mV to 3.5V
Synchronous Rectification
Adjustable operation from 80KHz to 1MHz
Integrated Power Good and Enable functions
Overvoltage protection
Overcurrent protection
Drives N-channel MOSFETs
20 pin SOIC or TSSOP package
Applications
•
•
•
•
Power supply DDR SDRAM VTT
Power Supply HSTL
Power Supply for ASICs
Adjustable ultra-low voltage step-down power supply
Block Diagram
+12V
+5V
FAN5066
1
5
4
–
+
OSC
–
+
–
13
+
12
–
+
+5V
DIGITAL
CONTROL
VO
7
9
CNTRL
VREF
16
20
1.24V
REFERENCE
4-BIT
DAC
19 18
17
8
VID2
VID4
VID1
VID3
POWER
GOOD
3
PWRGD
2
ENABLE
PRELIMINARY INFORMATION describes products that are not in full production at the time of printing. Specifications are based on design goals
and limited characterization. They may change without notice. Contact Fairchild Semiconductor for current information.REV. 2.1.4 11/13/01
FAN5066
PRODUCT SPECIFICATION
Pin Assignments
CEXT
1
20
VREF
ENABLE
2
19
VID1
PWRGD
3
18
VID2
IFB
4
17
VID3
VFB
5
16
CNTRL
VCCA
6
15
GNDA
VCCP
7
14
GNDD
VID4
8
13
VCCQP
LODRV
9
12
HIDRV
GNDP
10
11
GNDP
FAN5066
Pin Definitions
Pin Number Pin Name
1
CEXT
2
ENABLE
Output Enable. A logic LOW on this pin will disable the output. An internal pull-up
resistor allows for either open collector or TTL compatibility.
3
PWRGD
Power Good Flag. An open collector output that will be at logic LOW if the output
voltage is not within ±12% of the nominal output voltage setpoint.
4
IFB
High Side Current Feedback. Pins 4 and 5 are used as the inputs for the current
feedback control loop. Layout of these traces is critical to system performance. See
Application Information for details.
5
VFB
Voltage Feedback. Pin 5 is used as the input for the voltage feedback control loop and
as the low side current feedback input. See Application Information for details regarding
correct layout.
6
VCCA
Analog VCC. Connect to system 5V supply and decouple with a 0.1µF ceramic
capacitor.
7
VCCP
Power VCC for low side FET driver. Connect to system 5V supply and place a 1µF
ceramic capacitor for decoupling and local charge storage.
8
VID4
VID4 Input. A logic 1 on this open collector/TTL input will enable the VID3–VID0 inputs
to set the output from 2.1V to 3.5V, and a logic 0 will set the output from 1.3V to 2.05V,
as shown in Table 1. Pullup resistors are internal to the controller.
9
LODRV
Low Side FET Driver. Connect this pin to the gate of an N-channel MOSFET for
synchronous operation. The trace from this pin to the MOSFET gate should be < 0.5".
10, 11
GNDP
Power Ground. Return pin for high currents flowing in pins 7 and 13 (VCCP and
VCCQP). Connect to a low impedance ground.
12
HIDRV
High Side FET Driver. Connect this pin to the gate of an N-channel MOSFET. The
trace from this pin to the MOSFET gate should be < 0.5".
13
VCCQP
Power VCC. For high side FET driver. VCCQP must be connected to a voltage of at
least VCCA + VGS,ON (MOSFET), and place a 1µF ceramic capacitor for decoupling
and local charge storage. See Application Information for details
14
GNDD
Digital Ground. Return path for digital logic. Connect to a low impedance system
ground plane to minimize ground loops.
15
GNDA
Analog Ground. Return path for low power analog circuitry. This pin should be
connected to a low impedance system ground plane to minimize ground loops.
16
CNTRL
Voltage Control. The voltage forced on this pin determines the output voltage of the
converter.
17-19
20
2
Pin Function Description
Oscillator Capacitor Connection. Connecting an external capacitor to this pin sets
the internal oscillator frequency. Layout of this pin is critical to system performance.
See Application Information for details.
VID1-VID3 Voltage Identification Code Inputs. These open collector/TTL compatible inputs will
program the output voltage of the reference over the ranges specified in Table 1.
Pull-up resistors are internal to the controller.
VREF
Reference Voltage Test Point. This pin provides access to the DAC output and should
be decoupled to ground using 0.1µF capacitor.
REV. 2.1.4 11/13/01
PRODUCT SPECIFICATION
FAN5066
Absolute Maximum Ratings
Supply Voltages, VCCA, VCCP, VCCQP to GND
13V
Supply Voltage VCCQP, Charge Pump (VIN+VCCA)
18V
Voltage Identification Code Inputs, VID3-VID0
13V
VREF Output Current
3mA
150°C
Junction Temperature, TJ
-65 to 150°C
Storage Temperature
300°C
Lead Soldering Temperature, 10 seconds
Operating Conditions
Parameter
Supply Voltage, VCCA, VCCP
Conditions
Min.
4.75
Input Logic HIGH
Typ.
5
Max.
5.25
2.0
V
Input Logic LOW
Ambient Operating Temp
Output Driver Supply, VCCQP
Units
V
0.8
V
0
70
°C
8.5
12
V
Electrical Specifications
(VCCA = 5V, VCNTRL = 900mV, fosc = 300 KHz, and TA = +25°C using circuit in Figure 1, unless otherwise noted)
The • denotes specifications which apply over the full operating temperature range.
Parameter
Conditions
Min.
Typ.
Max.
Units
Initial Voltage Setpoint
ILOAD = 0.8A, VCTRL = 1.25V
VCTRL = 900mV
1.237
891
1.250
900
1.263
909
V
mV
Output Temperature Drift
TA = 0 to 70°C VOUT = 1.25V
VOUT = 900mV
•
•
+6
+4
mV
mV
Load Regulation
ILOAD = 0.8A to 3A
•
-20
mV
Line Regulation
VIN = 4.75V to 5.25V
•
±2
mV
Output Ripple
20MHz BW, ILOAD = 3A
DAC Output Voltage
See Table 1
±13
DAC Accuracy
•
Short Circuit Detect Threshold
Output Driver Rise and Fall Time
See Figure 3
Output Driver Deadtime 1
Output Driver Deadtime 2
Turn-on Response Time
ILOAD = 0A to 3A
3.4
V
-3
+3
%
150
mV
90
nsec
See Figure 3
5
%/fOSC
See Figure 3
80
nsec
80
Oscillator Frequency
CEXT = 100 pF
270
PWRGD threshold
Logic High
Logic Low
93
88
PWRGD Minimum Operating
Voltage
Max Duty Cycle
REV. 2.1.4 11/13/01
120
80
Oscillator Range
Control Pin Input Current
mVpk
1.3
90
VCTRL = 400mV to 3.5V
•
300
10
msec
1000
KHz
330
KHz
107
112
%VOUT
%VOUT
1.0
V
95
%
235
µA
3
FAN5066
PRODUCT SPECIFICATION
Table 1. DAC Output Voltage Programming Codes
VID4
VID3
VID2
VID1
0
1
1
1
VREF
1.30V
0
1
1
0
1.40V
0
1
0
1
1.50V
0
1
0
0
1.60V
0
0
1
1
1.70V
0
0
1
0
1.80V
0
0
0
1
1.90V
0
0
0
0
2.00V
1
1
1
1
No Output
1
1
1
0
2.2V
1
1
0
1
2.4V
1
1
0
0
2.6V
1
0
1
1
2.8V
1
0
1
0
3.0V
1
0
0
1
3.2V
1
0
0
0
3.4V
Note:
1. 0 = processor pin is tied to GND.
1 = processor pin is open.
4
REV. 2.1.4 11/13/01
PRODUCT SPECIFICATION
FAN5066
Typical Operating Characteristics
(VCCA, VCCD = 5V, fOSC = 280 KHz, and TA = +25°C using circuit in Figure 1, unless otherwise noted)
Load Regulation VOUT = 0.9V
0.895
70
0.890
60
VOUT (V)
Efficiency (%)
Efficiency vs. Output Current
80
50
40
0.885
0.880
0.875
30
0.870
20
0.1 0.3
0
0.6
0.9
1.2
1.5
1.8
2.1
2.4
2.7
0.5
1
3
1.5
2
2.5
3
Output Current (A)
Output Current (A)
Output Voltage vs. Output Current,
RSENSE = 6mΩ
Oscillator Frequency vs. CEXT
1250
1.2
1050
Frequency (KHz)
1.4
VOUT (V)
1.0
0.8
0.6
0.4
0.2
0
850
650
450
250
50
0
1
2
3
Output Current (A)
REV. 2.1.4 11/13/01
4
5
18
39
75
150
300
560
CEXT (pf)
5
FAN5066
PRODUCT SPECIFICATION
Typical Operating Characteristics (continued)
Transient Response, 3A to 0.1A
VOUT (20mV/div)
VOUT (20mV/div)
Output Ripple, 900m @ 3A
Time (10µs/division)
Time (1µs/division)
VOUT (20mV/div)
Transient Response, 0.1A to 3A
Time (1µs/division)
2V/div
HIDRV
pin
LODRV
pin
Time (1µs/division)
VOUT (500mV/div)
Output Startup, System Power-up
VIN (2V/div )
5V/div
Switching Waveforms, 3A Load
Time (5ms/division)
65-5051-12
6
REV. 2.1.4 11/13/01
PRODUCT SPECIFICATION
FAN5066
Application Circuit
+12V
L1
+5V
C1
2.2 µH
CIN
330µF
0.1µF
C2
0.1µF
R1
47Ω
D1
1N4735A
C6
0.1µF
C5
1µF
+5V
FDS6984S
R2
Q1
R5
2KΩ
U2
FAN4041
R6
324Ω
R7
909Ω
C9
0.1µF
11
10
9
12
8
13
14
7
15
6
U1
16 FAN5066 5
4
17
3
18
2
19
1
20
C4
1µF
4.7Ω
L2
R3
4.7µH
Q2
4.7Ω
R SENSE
VO
25mΩ
COUT
470µF
CEXT
C3 100pF
0.1µF
VID4
VID3
VID2
VCC
ENABLE
C7
0.1µF
R4
10KΩ
C8
0.1µF
PWRGD
VID1
Figure 1. Application Circuit for 900mV @ 3A
REV. 2.1.4 11/13/01
7
FAN5066
PRODUCT SPECIFICATION
Table 2. FAN5066 Application Bill of Materials for 900mV @ 3A
Reference
Manufacturer Part #
Quantity
Description
Requirements/Comments
C1–3, C6–C9
Panasonic
ECU-V1H104ZFX
7
100nF, 50V Capacitor
C4–5
Panasonic
ECU-V1C105ZFX
2
1µF, 16V Capacitor
Cext
Panasonic
ECU-V1H101JCG
1
100pF Capacitor
5%, C0G
CIN
AVX
TPSE337*010R0100
1
330µF, 10V Tantalum
Irms = 1.3A
COUT
AVX
TPSE477*006R0100
1
470µF, 6.3V Tantalum
ESR = 100mΩ
D1
Motorola
1N4735A
1
6.2V Zener Diode
L1
Coiltronics
MP2-2R2
1
2.2µH, 1.4A Inductor
DCR ~ 130mΩ
See Note 1.
L2
Coiltronics
UP2B-4R7
1
4.7µH, 5A inductor
DCR ~ 17mΩ
Q1
Fairchild
FDS6984S
1
N-Channel MOSFET with
Integrated Schottky
R1
Any
1
47Ω
R2-3
Any
2
4.7Ω
R4
Any
1
10KΩ
R5
Any
1
2.0KΩ
R6
Any
1
324Ω
R7
Any
1
909Ω
RSENSE
Any
1
25mΩ
U1
Fairchild
FAN5066M
1
DC/DC Controller
U2
Fairchild
FAN4041
1
Shunt Regulator
Notes:
1. Inductor L1 is recommended to isolate the 5V input supply from noise generated by the MOSFET switching. L1 may be
omitted if desired.
8
REV. 2.1.4 11/13/01
PRODUCT SPECIFICATION
FAN5066
Application Circuit
+12V
L1
+5V
C1
1.5µH
0.1µF
C11
680µF
C2
0.1µF
R1
47Ω
D1
1N4735A
C6
0.1µF
C5
1µF
R2
Q1
VDDQ
R5
499
R6
499
11
10
9
12
8
13
14
7
U1
15
6
FAN5066
16
5
17
4
18
3
19
2
20
1
C4
1µF
4.7Ω
L2
R3
1.5µH
Q2
4.7Ω
VO
COUT*
C10
C9 100pF
0.1µF
VCC
ENABLE
C7
0.1µF
R4
10KΩ
C8
0.1µF
PWRGD
*Refer to Table 3 for value
of COUT.
Figure 2. 12A Application Circuit for DDR VTT
REV. 2.1.4 11/13/01
9
FAN5066
PRODUCT SPECIFICATION
Table 3. FAN5066 Application Bill of Materials for DDR VTT
Reference
Manufacturer Part #
Quantity
Description
Requirements/Comments
C1–2, C6–C9
Panasonic
ECU-V1H104ZFX
6
100nF, 50V Capacitor
C4–5
Panasonic
ECU-V1C105ZFX
2
1µF, 16V Capacitor
C10
Panasonic
ECU-V1H101JCG
1
100pF Capacitor
5%, C0G
C11
Sanyo
6SP680M
1
680µF, 6.3V OSCON
IRMS = 4.8A
COUT
Sanyo
4SP820M
4
820µF, 4V OSCON
ESR < 12mΩ
D1
Motorola
1N4735A
1
6.2V Zener Diode
L1
Coiltronics
UP1B-1R5
Optional
1.5µH, 4A Inductor
DCR ~ 20mΩ
See Note 1.
L2
Coiltronics
UP4B-1R5
1
1.5µH, 13A Inductor
DCR ~ 4mΩ
Q1–2
Fairchild
FDS6680S
2
N-Channel MOSFET
w/ Integrated Schottky
RDS(ON) = 17mΩ @
VGS = 4.5V
R1
Any
1
47Ω
R2-3
Any
2
4.7Ω
R4
Any
1
10KΩ
R5-6
Any
2
499Ω
U1
Fairchild
FAN5066M
1
DC/DC Controller
Notes:
1. Inductor L1 is recommended to isolate the 5V input supply from noise generated by the MOSFET switching. L1 may be
omitted if desired.
Test Circuit
+12V
47Ω
1µF
tR
VCCQP
+5V
VCCA
HIDRV
tF
90%
4.7Ω
HIDRV
50%
0.1µF
90%
50%
3000pF
10%
tDT1
4.7Ω
VCCP
10%
tDT2
LODRV
1µF
3000pF
50%
50%
LODRV
GNDA GNDD GNDP
Figure 3. Output Drive Test Circuit and Timing Diagram
10
REV. 2.1.4 11/13/01
PRODUCT SPECIFICATION
Application Information
The FAN5066 Controller
The FAN5066 is a programmable synchronous DC-DC controller IC. When designed around the appropriate external
components, the FAN5066 can be configured to deliver more
than 19A of output current. The FAN5066 functions as a
fixed frequency PWM step down regulator.
Main Control Loop
Refer to the FAN5066 Block Diagram on page 1. The
FAN5066 implements “summing mode control”, which is
different from both classical voltage-mode and current-mode
control. It provides superior performance to either by allowing a large converter bandwidth over a wide range of output
loads.
The control loop of the regulator contains two main sections:
the analog control block and the digital control block. The
analog section consists of signal conditioning amplifiers
feeding into a set of comparators which provide the inputs to
the digital control block. The signal conditioning section
accepts inputs from the IFB (current feedback) and VFB
(voltage feedback) pins and sets up two controlling signal
paths. The first, the voltage control path, amplifies the difference between the VFB signal the reference voltage from the
DAC and presents the output to one of the summing amplifier inputs. The second, current control path, takes the difference between the IFB and VFB pins and presents the
resulting signal to another input of the summing amplifier.
These two signals are then summed together with the slope
compensation input from the oscillator. This output is then
presented to a comparator, which provides the main PWM
control signal to the digital control block.
The digital control block takes the analog comparator inputs
and the main clock signal from the oscillator to provide the
appropriate pulses to the HIDRV and LODRV output pins.
These two outputs control the external power MOSFETs.
The digital block utilizes high speed Schottky transistor
logic, allowing the FAN5066 to operate at clock speeds as
high as 1MHz.
There are additional comparators in the analog control section whose function is to set the point at which the FAN5066
enters its pulse skipping mode during light loads, as well as
the point at which the current limit comparator disables the
output drive signals to the external power MOSFETs.
High Current Output Drivers
The FAN5066 contains two identical high current output
drivers that utilize high speed bipolar transistors in a pushpull configuration. The drivers’ power and ground are separated from the chip’s power and ground for switching noise
immunity. The HIDRV driver has a power supply pin,
REV. 2.1.4 11/13/01
FAN5066
VCCQP, which is supplied from an external 12V source
through a series resistor or from a charge-pump circuit
powered from 5V if 12V is not available. The LODRV driver
has a power supply pin, VCCP, which can be supplied from
either the 12V or 5V source. The resulting voltages are sufficient to provide the gate to source drive to the external
MOSFETs required in order to achieve a low RDS,ON.
Power Good (PWRGD)
The FAN5066 Power Good function is designed in accordance with the Pentium II DC-DC converter specifications
and provides a continuous voltage monitor on the VFB pin.
The circuit compares the VFB signal to the VREF voltage
and outputs an active-low interrupt signal to the CPU should
the power supply voltage deviate more than ±12% of its
nominal setpoint. The Power Good flag provides no other
control function to the FAN5066.
Output Enable (ENABLE)
The FAN5066 will accept an open collector/TTL signal for
controlling the output voltage. The low state disables the output voltage. When disabled, the PWRGD output is in the low
state. If an enable is not required in the circuit, this pin may
be left open.
Over-Voltage Protection
The FAN5066 constantly monitors the output voltage for
protection against over voltage conditions. If the voltage at
the VFB pin exceeds 20% of the selected program voltage,
an over-voltage condition is assumed and the FAN5066 disables the output drive signal to the external MOSFETs. The
DC-DC converter returns to normal operation after the fault
has been removed.
Over-Current Protection
Current sense is implemented in the FAN5066 to reduce the
duty cycle of the output drive signal to the MOSFETs when
an over-current condition is detected. The voltage drop
created by the output current flowing across a sense resistor
is presented to an internal comparator. When the voltage
developed across the sense resistor exceeds the 120mV comparator threshold voltage, the FAN5066 reduces the output
duty cycle to help protect the power devices. The DC-DC
converter returns to normal operation after the fault has been
removed.
Oscillator
The FAN5066 oscillator section uses a fixed current capacitor charging configuration. An external capacitor (CEXT) is
used to set the oscillator frequency between 80KHz and
1MHz. This scheme allows maximum flexibility in choosing
external components.
11
FAN5066
In general, a higher operating frequency decreases the peak
ripple current flowing in the output inductor, thus allowing
the use of a smaller inductor value. In addition, operation at
higher frequencies decreases the amount of energy storage
that must be provided by the bulk output capacitors during
load transients due to faster loop response of the controller.
Unfortunately, the efficiency losses due to switching of the
MOSFETs increase as the operating frequency is increased.
Thus, efficiency is optimized at lower frequencies. An operating frequency of 300KHz is a typical choice which optimizes efficiency and minimizes component size while
maintaining excellent regulation and transient performance
under all operating conditions.
PRODUCT SPECIFICATION
mately 4.5V. When the MOSFET Q1 turns on, the voltage at
the source of the MOSFET is equal to 5V. The capacitor
voltage follows, and hence provides a voltage at VCCQP
equal to almost 10V. The Schottky diode D1 is required to
provide the charge path when the MOSFET is off, and
reverses biases when VCCQP goes to 10V. The charge pump
capacitor (CP) needs to be a high Q, high frequency capacitor. A 1µF ceramic capacitor is recommended here.
+5V
Q1
HIDRV
Design Considerations and Component
Selection
Additional information on design and component selection
may be found in Fairchild Semiconductor’s Application
Note 53.
D1
VCCQP
CP
L2
RS
VO
PWM/PFM
Control
COUT
LODRV
Q2
D2
GNDP
MOSFET Selection
This application requires N-channel Logic Level Enhancement Mode Field Effect Transistors. Desired characteristics
are as follows:
• Low Static Drain-Source On-Resistance,
RDS,ON < 20mΩ (lower is better)
• Low gate drive voltage, VGS = 4.5V rated
• Power package with low Thermal Resistance
• Drain-Source voltage rating > 15V.
The on-resistance (RDS,ON) is the primary parameter for
MOSFET selection. The on-resistance determines the power
dissipation within the MOSFET and therefore significantly
affects the efficiency of the DC-DC Converter. For details
and a spreadsheet on MOSFET selection, refer to Applications Bulletin AB-8
Figure 4. Charge Pump Configuration
Method 2. 12V Gate Bias
Figure 5 illustrates how a 12V source can be used to bias
VCCQP. A 47Ω resistor is used to limit the transient current
into the VCCQP pin and a 1µF capacitor is used to filter the
VCCQP supply. This method provides a higher gate bias
voltage (VGS) to the high side MOSFET than the charge
pump method, and therefore reduces the RDS,ON and the
resulting power loss within the MOSFET. In designs where
efficiency is a primary concern, the 12V gate bias method is
recommended. A 6.2V Zener diode, D1, is used to clamp the
voltage at VCCQP to a maximum of 12V and ensure that the
absolute maximum voltage of the IC will not be exceeded.
+5V
MOSFET Gate Bias
+12V
The high side MOSFET gate driver can be biased by one of
two methods–Charge Pump or 12V Gate Bias. The charge
pump method has the advantage of requiring only +5V as an
input voltage to the converter, but the 12V method will realize increased efficiency by providing an increased VGS to the
high side MOSFETs.
Method 1. Charge Pump (Bootstrap)
Figure 4 shows the use of a charge pump to provide gate bias
to the high side MOSFET when +12V is unavailable. Capacitor CP is the charge pump used to boost the voltage of the
FAN5066 output driver. When the MOSFET Q1 switches
off, the source of the MOSFET is at approximately 0V
because of the MOSFET Q2. (The Schottky D2 conducts for
only a very short time, and is not relevent to this discussion.)
CP is charged through the Schottky diode D1 to approxi-
12
47Ω
D1
VCCQP
Q1
HIDRV
1µF
L2
RS
VO
PWM/PFM
Control
COUT
LODRV
Q2
D2
GNDP
Figure 5. Gate Bias Configuration
REV. 2.1.4 11/13/01
PRODUCT SPECIFICATION
FAN5066
Inductor Selection
( V in – V out ) V out
ESR
L min = ------------------------------ × ----------- × ----------------V in V ripple
f
3.0
2.5
2.0
1.5
1.0
0.5
where:
Vin = Input Power Supply
Vout = Output Voltage
f = DC/DC converter switching frequency
ESR = Equivalent series resistance of all output capacitors in
parallel
Vripple = Maximum peak to peak output ripple voltage
budget.
The first order equation for maximum allowed inductance is:
L max
Output Voltage vs. Output Current
RSENSE = 6mΩ
3.5
OUT (V)
Choosing the value of the inductor is a tradeoff between
allowable ripple voltage and required transient response. The
system designer can choose any value within the allowed
minimum to maximum range in order to either minimize ripple or maximize transient performance. The first order equation (close approximation) for minimum inductance is:
( V in – V out )D m V tb
= 2C O × ----------------------------------------------2
I PP
where:
Co = The total output capacitance
Ipp = Maximum to minimum load transient current
Vtb = The output voltage tolerance budget allocated to load
transient
Dm = Maximum duty cycle for the DC/DC converter
(usually 95%).
Some margin should be maintained away from both Lmin
and Lmax. Adding margin by increasing L almost always
adds expense since all the variables are predetermined by
system performance except for Co, which must be increased
to increase L. Adding margin by decreasing L can either be
done by purchasing capacitors with lower ESR or by increasing the DC/DC converter switching frequency. The
FAN5066 is capable of running at high switching frequencies and provides significant cost savings for the newer CPU
systems that typically run at high supply current.
FAN5066 Short Circuit Current Characteristics
The FAN5066 short circuit current characteristic includes a
hysteresis function that prevents the DC-DC converter from
oscillating in the event of a short circuit. Figure 6 shows the
typical characteristic of the DC-DC converter circuit with a
6.8 mΩ sense resistor. The converter exhibits a normal load
regulation characteristic until the voltage across the resistor
exceeds the internal short circuit threshold of 120mV
(= 17.5A * 6.8mΩ). At this point, the internal comparator
trips and signals the controller to reduce the converter’s
duty cycle to approximately 20%. This causes a drastic
reduction in the output voltage as the load regulation
collapses into the short circuit control mode. With a 40mΩ
output short,the voltage is reduced to 15A * 40mΩ = 600mV.
REV. 2.1.4 11/13/01
0
0
5
10
15
20
25
Output Current (A)
Figure 6. FAN5066 Short Circuit Characteristic
The output voltage does not return to its nominal value until
the output current is reduced to a value within the safe operating range for the DC-DC converter
Schottky Selection
A schottky diode is not required in Figures 1 and 2, because
the low-side MOSFETs have built in schottkies using Fairchild SyncFET technology. If some other type of MOSFET
is used, a schottky must be used in anti-parallel with the lowside MOSFET. Selection of a schottky is determined by the
maximum output. In the converter of Figure 1, maximum
output current is 3A, and suppose the MOSFET has a body
diode Vf = 0.75V at this current. The schottky must have at
least 100mV less Vf at the same current to ensure that the
body diode does not turn on. The MBRS130L diode has Vf =
0.45V typical at 3A at 25°C, and so is a suitable choice.
Output Filter Capacitors
The output bulk capacitors of a converter help determine its
output ripple voltage and its transient response. It has
already been seen in the section on selecting an inductor that
the ESR helps set the minimum inductance, and the capacitance value helps set the maximum inductance. For most
converters, however, the number of capacitors required is
determined by the transient response and the output ripple
voltage, and these are determined by the ESR and not the
capacitance value. That is, in order to achieve the necessary
ESR to meet the transient and ripple requirements, the
capacitance value required is already very large.
The most commonly used choice for output bulk capacitors
is aluminum electrolytics, because of their low cost and low
ESR. The only type of aluminum capacitor used should be
those that have an ESR rated at 100kHz. Consult Application
Bulletin AB-14 for detailed information on output capacitor
selection.
The output capacitance should also include a number of
small value ceramic capacitors placed as close as possible to
the processor; 0.1µF and 0.01µF are recommended values.
13
FAN5066
PRODUCT SPECIFICATION
Input Filter
PCB Layout Guidelines
The DC-DC converter design may include an input inductor
between the system +5V supply and the converter input as
shown in Figure 6. This inductor serves to isolate the +5V
supply from the noise in the switching portion of the DC-DC
converter, and to limit the inrush current into the input capacitors during power up. A value of 2.5µH is recommended.
• Placement of the MOSFETs relative to the FAN5066 is
critical. Place the MOSFETs such that the trace length of
the HIDRV and LODRV pins of the FAN5066 to the FET
gates is minimized. A long lead length on these pins will
cause high amounts of ringing due to the inductance of the
trace and the gate capacitance of the FET. This noise
radiates throughout the board, and, because it is switching
at such a high voltage and frequency, it is very difficult to
suppress.
• In general, all of the noisy switching lines should be kept
away from the quiet analog section of the FAN5066. That
is, traces that connect to pins 9, 12, and 13 (LODRV,
HIDRV and VCCQP) should be kept far away from the
traces that connect to pins 1 through 5, and pin 16.
• Place the 0.1µF decoupling capacitors as close to the
FAN5066 pins as possible. Extra lead length on these
reduces their ability to suppress noise.
• Each VCC and GND pin should have its own via to the
appropriate plane. This helps provide isolation between
pins.
• Surround the CEXT timing capacitor with a ground trace.
Be sure to place a ground or power plane underneath the
capacitor for further noise isolation, in order to provide
additional shielding to the oscillator (pin 1) from the noise
on the PCB. In addition, place this capacitor as close to
pin 1 as possible.
• Place the MOSFETs, inductor, and Schottky as close
together as possible for the same reasons as in the first
bullet above. Place the input bulk capacitors as close to
the drains of the high side MOSFETs as possible. In
addition, placement of a 0.1µF decoupling cap right on
the drain of each high side MOSFET helps to suppress
some of the high frequency switching noise on the input
of the DC-DC converter.
• Place the output bulk capacitors as close to the CPU as
possible to optimize their ability to supply instantaneous
current to the load in the event of a current transient.
Additional space between the output capacitors and the
CPU will allow the parasitic resistance of the board traces
to degrade the DC-DC converter’s performance under
severe load transient conditions, causing higher voltage
deviation. For more detailed information regarding
capacitor placement, refer to Application Bulletin AB-5.
• The traces that run from the FAN5066 IFB (pin 4) and
VFB (pin 5) pins should be run together next to each other
and Kelvin connected to the sense resistor. Running these
lines together rejects some of the common mode noise
that is presented to the FAN5066 feedback input. Try, as
much as possible, to run the noisy switching signals
(HIDRV, LODRV & VCCQP) on one layer, but use the
inner layers for power and ground only. If the top layer is
being used to route all of the noisy switching signals, use
the bottom layer to route the analog sensing sign VFB and
IFB.
• A PC Board Layout Checklist is available from Fairchild
Applications. Ask for Application Bulletin AB-11.
It is necessary to have some low ESR aluminum electrolytic
capacitors at the input to the converter. These capacitors
deliver current when the high side MOSFET switches on.
Figure 7 shows 3 x 1000µF, but the exact number required
will vary with the speed and type of the processor. For the
top speed Klamath and Deschutes, the capacitors should be
rated to take 7A of ripple current. Capacitor ripple current
rating is a function of temperature, and so the manufacturer
should be contacted to find out the ripple current rating at the
expected operational temperature. For details on the design
of an input filter, refer to Applications Bulletin AB-15.
2.5µH
5V
Vin
1000µF, 10V
Electrolytic
0.1µF
Figure 7. Input Filter
Droop Resistor
Figure 8 shows a converter using a “droop resistor”, RD. The
function of the droop resistor is to improve the transient
response of the converter, potentially reducing the number of
output capacitors required. In operation, the droop resistor
causes the output voltage to be slightly lower at heavy load
current than it otherwise would be. When the load transitions
from heavy to light current, the output can swing up farther
without exceeding limits, because it started from a lower
voltage, thus reducing the capacitor requirements.
Q1
RSENSE
L2
RDROOP
VO
Q2
IFB
VFB
COUT
Figure 8. Use of a Droop Resistor
14
REV. 2.1.4 11/13/01
PRODUCT SPECIFICATION
FAN5066
Additional Information
For additional information contact your local Fairchild
Semiconductor representative, or visit us on our website at
www.fairchildsemi.com.
REV. 2.1.4 11/13/01
15
FAN5066
PRODUCT SPECIFICATION
Mechanical Dimensions – 20 Lead SOIC
Inches
Symbol
Min.
A
A1
B
C
D
E
e
H
h
L
N
α
ccc
Notes:
Millimeters
Max.
Min.
Notes
.093
.104
.004
.012
.013
.020
.009
.013
.496
.512
.291
.299
.050 BSC
2.35
2.65
0.10
0.30
0.33
0.51
0.23
0.32
12.60
13.00
7.40
7.60
1.27 BSC
.394
.010
.016
10.00
0.25
0.40
.419
.029
.050
20
1. Dimensioning and tolerancing per ANSI Y14.5M-1982.
Max.
10.65
0.75
1.27
20
0°
8°
0°
8°
—
.004
—
0.10
2. "D" and "E" do not include mold flash. Mold flash or
protrusions shall not exceed .010 inch (0.25mm).
3. "L" is the length of terminal for soldering to a substrate.
4. Terminal numbers are shown for reference only.
5
2
2
5. "C" dimension does not include solder finish thickness.
6. Symbol "N" is the maximum number of terminals.
3
6
11
20
E
H
10
1
h x 45°
D
C
A1
A
e
B
SEATING
PLANE
–C–
LEAD COPLANARITY
α
L
ccc C
16
REV. 2.1.4 11/13/01
PRODUCT SPECIFICATION
FAN5066
Mechanical Dimensions – 20 Lead TSSOP
Inches
Symbol
Min.
A
A1
B
C
D
E
e
H
Max.
Min.
—
.047
.002
.006
.007
.012
.004
.008
.252
.260
.169
.177
.026 BSC
.252 BSC
.018
.030
L
N
α
ccc
Notes:
Millimeters
Notes
Max.
2. "D" and "E" do not include mold flash. Mold flash or
protrusions shall not exceed .006 inch (0.15mm).
—
1.20
0.05
0.15
0.19
0.30
0.09
0.20
6.40
6.60
4.30
4.50
0.65 BSC
6.40 BSC
0.45
0.75
20
3. "L" is the length of terminal for soldering to a substrate.
4. Terminal numbers are shown for reference only.
5. Symbol "N" is the maximum number of terminals.
2
2
3
5
20
0°
8°
0°
8°
—
.004
—
0.10
1. Dimensioning and tolerancing per ANSI Y14.5M-1982.
D
E
H
C
A1
A
B
e
SEATING
PLANE
–C–
α
L
LEAD COPLANARITY
ccc C
REV. 2.1.4 11/13/01
17
FAN5066
PRODUCT SPECIFICATION
Ordering Information
Product Number
FAN5066M
Package
20 pin SOIC
FAN5066MTC
20 pin TSSOP
FAN5066MTCX
20 pin TSSOP
DISCLAIMER
FAIRCHILD SEMICONDUCTOR RESERVES THE RIGHT TO MAKE CHANGES WITHOUT FURTHER NOTICE TO ANY
PRODUCTS HEREIN TO IMPROVE RELIABILITY, FUNCTION OR DESIGN. FAIRCHILD DOES NOT ASSUME ANY
LIABILITY ARISING OUT OF THE APPLICATION OR USE OF ANY PRODUCT OR CIRCUIT DESCRIBED HEREIN; NEITHER
DOES IT CONVEY ANY LICENSE UNDER ITS PATENT RIGHTS, NOR THE RIGHTS OF OTHERS.
LIFE SUPPORT POLICY
FAIRCHILD’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES
OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF FAIRCHILD SEMICONDUCTOR
CORPORATION. As used herein:
1. Life support devices or systems are devices or systems
which, (a) are intended for surgical implant into the body,
or (b) support or sustain life, or (c) whose failure to perform
when properly used in accordance with instructions for use
provided in the labeling, can be reasonably expected to
result in significant injury to the user.
2. A critical component is any component of a life support
device or system whose failure to perform can be
reasonably expected to cause the failure of the life support
device or system, or to affect its safety or effectiveness.
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11/13/01 0.0m 001
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