ONSEMI CS5166GDWR16

CS5166
5−Bit Synchronous CPU
Controller with Power Good
and Current Limit
The CS5166 is a synchronous dual NFET buck controller. It is
designed to power the core logic of the latest high performance CPUs. It
uses V2™ control method to achieve the fastest possible transient
response and best overall regulation. It incorporates many additional
features required to ensure the proper operation and protection of the
CPU and power system. The CS5166 provides the industry’s most
highly integrated solution, minimizing external component count, total
solution size, and cost.
The CS5166 is specifically designed to power Intel’s Pentium®II
processor and includes the following features: 5−bit DAC with 1.0%
tolerance, Power Good output, adjustable hiccup mode overcurrent
protection, VCC monitor, Soft Start, adaptive voltage positioning,
overvoltage protection, remote sense and current sharing capability.
The CS5166 will operate over a 4.15 to 14 V range using either
single or dual input voltage and is available in a 16 lead wide body
surface mount package.
Features
• V2 Control Topology
• Dual N−Channel Design
• 125 ns Controller Transient Response
• Excess of 1.0 MHz Operation
• 5−Bit DAC with 1.0% Tolerance
• Power Good Output With Internal Delay
• Adjustable Hiccup Mode Overcurrent Protection
• Complete Pentium II System Requires Just 21 Components
• 5.0 V & 12 V Operation
• Adaptive Voltage Positioning
• Remote Sense Capability
• Current Sharing Capability
• VCC Monitor
• Overvoltage Protection (OVP)
• Programmable Soft Start
• 200 ns PWM Blanking
• 65 ns FET Nonoverlap Time
• 40 ns Gate Rise and Fall Times (3.3 nF Load)
© Semiconductor Components Industries, LLC, 2006
July, 2006 − Rev. 4
1
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MARKING
DIAGRAM
16
16
1
CS5166
SO−16L
DW SUFFIX
CASE 751G
AWLYYWW
1
A
WL, L
YY, Y
WW, W
= Assembly Location
= Wafer Lot
= Year
= Work Week
PIN CONNECTIONS
VID0
VID1
VID2
VID3
SS
VID4
COFF
1
16
VFB
COMP
LGND
PWRGD
GATE(L)
PGND
GATE(H)
VCC
ISENSE
ORDERING INFORMATION
Device
Package
Shipping
CS5166GDW16
SO−16L
46 Units/Rail
CS5166GDWR16
SO−16L
1000 Tape & Reel
Publication Order Number:
CS5166/D
CS5166
5.0 V
12 V
1200 μF/10 V × 3
1.0 μF
VCC
COFF
330 pF
SS
0.1 μF
0.1 μF
1.2 μH
3.0 mΩ
GATE(H)
COMP
510
ISENSE
1200 μF/10 V × 5
CS5166
PWRGD
GATE(L)
VID0
VID1
VID2
0.1 μF
PGND
VID4
LGND
VID3
Pentium II
System
VID2
VID3
VID4
VCC
VID1
3.3 k
PWRGD VFB
VID0
1000 pF
Figure 1. Application Diagram, 5.0 V to 2.8 V @ 14.2 A for 300 MHz Pentium II
ABSOLUTE MAXIMUM RATINGS*
Rating
Operating Junction Temperature, TJ
Lead Temperature Soldering:
Reflow: (SMD styles only) (Note 1)
Storage Temperature Range, TS
1. 60 second maximum above 183°C.
*The maximum package power dissipation must be observed.
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2
Value
Unit
0 to 150
°C
230 peak
°C
−65 to +150
°C
CS5166
ABSOLUTE MAXIMUM RATINGS
Pin Name
Pin Symbol
VMAX
VMIN
ISOURCE
ISINK
IC Power Input
VCC
16 V
−0.3 V
N/A
1.5 A peak, 200 mA DC
Soft Start Capacitor
SS
6.0 V
−0.3 V
200 μA
10 μA
Compensation Capacitor
COMP
6.0 V
−0.3 V
10 mA
1.0 mA
Voltage Feedback and Current
Sense Comparator Input
VFB
6.0 V
−0.3 V
1.0 mA
1.0 mA
Off−Time Capacitor
COFF
6.0 V
−0.3 V
1.0 mA
50 mA
Voltage ID DAC Inputs
VID0−VID4
6.0 V
−0.3 V
1.0 mA
10 μA
High−Side FET Driver
GATE(H)
16 V
−0.3 V
1.5 A peak, 200 mA DC
1.5 A peak, 200 mA DC
Low−Side FET Driver
GATE(L)
16 V
−0.3 V
1.5 A peak, 200 mA DC
1.5 A peak, 200 mA DC
Current Sense Comparator Input
ISENSE
6.0 V
−0.3 V
1.0 mA
1.0 mA
Power Good Output
PWRGD
6.0 V
−0.3 V
10 μA
30 mA
Power Ground
PGND
0V
0V
1.5 A peak, 200 mA DC
N/A
Logic Ground
LGND
0V
0V
100 mA
N/A
ELECTRICAL CHARACTERISTICS (0°C < TA < 70°C; 0°C < TJ < 125°C; 8.0 V < VCC < 14 V; 2.0 DAC Code:
(VID4 = VID3 = VID2 = VID1 = 0); CGATE(H) = CGATE(L) = 3.3 nF; COFF = 330 pF; CSS = 0.1 μF, unless otherwise specified.)
Test Conditions
Characteristic
Min
Typ
Max
Unit
−
12
20
mA
VCC Supply Current
Operating
1.0 V < VFB < VDAC (max on−time),
No Loads on GATE(H) and GATE(L)
VCC Monitor
Start Threshold
GATE(H) switching
3.75
3.95
4.15
V
Stop Threshold
GATE(H) not switching
3.65
3.87
4.05
V
Hysteresis
Start−Stop
−
80
−
mV
VFB Bias Current
VFB = 0 V
−
0.1
1.0
μA
COMP Source Current
COMP = 1.2 V to 3.6 V; VFB = 1.9 V
15
30
60
μA
COMP CLAMP Voltage
VFB = 1.9 V, Adjust COMP voltage for Comp
current = 60 μA
0.85
1.0
1.15
V
COMP Clamp Current
COMP = 0 V
0.4
1.0
1.6
mA
COMP Sink Current
VCOMP = 1.2 V; VFB = 2.2 V; VSS > 2.5 V
180
400
800
μA
Open Loop Gain
Note 2
50
60
−
dB
Unity Gain Bandwidth
Note 2
0.5
2.0
−
MHz
PSRR @ 1.0 kHz
Note 2
60
85
−
dB
Current Limit Voltage
VFB = 0 V to 3.5 V, 8.0 V < VCC < 12 V + 10%
55
76
130
mV
ISENSE Bias Current
ISENSE = 2.8 V
13
30
50
μA
Error Amplifier
Overcurrent Detection
2. Guaranteed by design, not 100% tested in production.
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CS5166
ELECTRICAL CHARACTERISTICS (continued) (0°C < TA < 70°C; 0°C < TJ < 125°C; 8.0 V < VCC < 14 V; 2.0 DAC Code:
(VID4 = VID3 = VID2 = VID1 = 0); CGATE(H) = CGATE(L) = 3.3 nF; COFF = 330 pF; CSS = 0.1 μF, unless otherwise specified.)
Characteristic
Test Conditions
Min
Typ
Max
Unit
GATE(H) and GATE(L)
High Voltage at 100 mA
Measure VCC − GATE
−
1.2
2.0
V
Low Voltage at 100 mA
Measure GATE
−
1.0
1.5
V
Rise Time
1.6 V < GATE < (VCC − 2.5 V)
−
40
80
ns
Fall Time
(VCC − 2.5 V) > GATE > 1.6 V
−
40
80
ns
GATE(H) to GATE(L) Delay
GATE(H) < 2.0 V; GATE(L) > 2.0 V
30
65
100
ns
GATE(L) to GATE(H) Delay
GATE(L) < 2.0 V; GATE(H) > 2.0 V
30
65
100
ns
GATE pull−down
Resistor to PGND, Note 3
20
50
115
kΩ
SS Charge Time
VFB = 3.0 V, VISENSE = 2.8 V
1.6
3.3
5.0
ms
SS Pulse Period
VFB = 3.0 V, VISENSE = 2.8 V
25
100
200
ms
SS Duty Cycle
(Charge Time/Period) × 100
1.0
3.3
6.0
%
SS COMP Clamp Voltage
VFB = 2.7 V; VSS = 0 V
0.50
0.95
1.10
V
VFB Low Comparator
Increase VFB till normal off−time
0.9
1.0
1.1
V
−
115
175
ns
Fault Protection
PWM Comparator
Transient Response
VFB = 1.2 to 5.0 V. 500 ns after GATE(H)
(after Blanking time) to GATE(H) = (VCC −1.0 V)
to 1.0 V
Minimum Pulse Width
(Blanking Time)
Drive VFB 1.2 V to 5.0 V upon GATE(H) rising
edge (> VCC − 1.0 V), measure GATE(H) pulse
width
100
200
300
ns
Normal Off−Time
VFB = 2.7 V
1.0
1.6
2.3
μs
Extended Off−Time
VSS = VFB = 0 V
5.0
8.0
12.0
μs
Time−Out Time
VFB = 2.7 V, Measure GATE(H) Pulse Width
10
30
50
μs
Fault Duty Cycle
VFB = 0V
30
50
70
%
Low to High Delay
VFB = (0.8 × VDAC) to VDAC
30
65
110
μs
High to Low Delay
VFB = VDAC to (0.8 × VDAC)
30
75
120
μs
Output Low Voltage
VFB = 2.4 V, IPWRGD = 500 μA
−
0.2
0.3
V
Sink Current Limit
VFB = 2.4 V, PWRGD = 1.0 V
0.5
4.0
15.0
mA
COFF
Time−Out Timer
Power Good Output
3. Guaranteed by design, not 100% tested in production.
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CS5166
ELECTRICAL CHARACTERISTICS (continued) (0°C < TA < 70°C; 0°C < TJ < 125°C; 8.0 V < VCC < 14 V; 2.0 DAC Code:
(VID4 = VID3 = VID2 = VID1 = 0); CGATE(H) = CGATE(L) = 3.3 nF; COFF = 330 pF; CSS = 0.1 μF, unless otherwise specified.)
Characteristic
Test Conditions
Min
Typ
Max
Unit
−1.0
−
+1.0
%
Voltage Identification DAC
Accuracy (all codes except 11111)
Measure VFB = COMP (COFF = GND)
25°C ≤ TJ ≤ 125°C; VCC = 12 V
VID4
VID3
VID2
VID1
VID0
1
0
0
0
0
−
3.489
3.525
3.560
V
1
0
0
0
1
−
3.390
3.425
3.459
V
1
0
0
1
0
−
3.291
3.325
3.358
V
1
0
0
1
1
−
3.192
3.225
3.257
V
1
0
1
0
0
−
3.093
3.125
3.156
V
1
0
1
0
1
−
2.994
3.025
3.055
V
1
0
1
1
0
−
2.895
2.925
2.954
V
1
0
1
1
1
−
2.796
2.825
2.853
V
1
1
0
0
0
−
2.697
2.725
2.752
V
1
1
0
0
1
−
2.598
2.625
2.651
V
1
1
0
1
0
−
2.499
2.525
2.550
V
1
1
0
1
1
−
2.400
2.425
2.449
V
1
1
1
0
0
−
2.301
2.325
2.348
V
1
1
1
0
1
−
2.202
2.225
2.247
V
1
1
1
1
0
−
2.103
2.125
2.146
V
0
0
0
0
0
−
2.054
2.075
2.095
V
0
0
0
0
1
−
2.004
2.025
2.045
V
0
0
0
1
0
−
1.955
1.975
1.994
V
0
0
0
1
1
−
1.905
1.925
1.944
V
0
0
1
0
0
−
1.856
1.875
1.893
V
0
0
1
0
1
−
1.806
1.825
1.843
V
0
0
1
1
0
−
1.757
1.775
1.792
V
0
0
1
1
1
−
1.707
1.725
1.742
V
0
1
0
0
0
−
1.658
1.675
1.691
V
0
1
0
0
1
−
1.608
1.625
1.641
V
0
1
0
1
0
−
1.559
1.575
1.590
V
0
1
0
1
1
−
1.509
1.525
1.540
V
0
1
1
0
0
−
1.460
1.475
1.489
V
0
1
1
0
1
−
1.410
1.425
1.439
V
0
1
1
1
0
−
1.361
1.375
1.388
V
0
1
1
1
1
−
1.311
1.325
1.338
V
1
1
1
1
1
−
1.219
1.247
1.269
V
Input Threshold
VID4, VID3, VID2, VID1, VID0
1.000
1.250
2.400
V
Input Pull−up Resistance
VID4, VID3, VID2, VID1, VID0
25
50
100
kΩ
4.85
5.00
5.15
V
Input Pull−up Voltage
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CS5166
ELECTRICAL CHARACTERISTICS (continued) (0°C < TA < 70°C; 0°C < TJ < 125°C; 8.0 V < VCC < 14 V; 2.0 DAC Code:
(VID4 = VID3 = VID21 = VID1 = 0); CGATE(H) = CGATE(L) = 3.3 nF; COFF = 330 pF; CSS = 0.1 μF, unless otherwise specified.)
Lower Threshold
Threshold Accuracy
Min
Typ
−12
−8.5
Upper Threshold
Max
Min
Typ
Max
Unit
−5.0
5.0
8.5
12
%
DAC CODE
% of Nominal DAC Output
VID4
VID3
VID2
VID1
VID0
1
0
0
0
0
3.102
3.225
3.348
3.701
3.824
3.948
V
1
0
0
0
1
3.014
3.133
3.253
3.596
3.716
3.836
V
1
0
0
1
0
2.926
3.042
3.158
3.491
3.607
3.724
V
1
0
0
1
1
2.838
2.950
3.063
3.386
3.499
3.612
V
1
0
1
0
0
2.750
2.859
2.968
3.281
3.390
3.500
V
1
0
1
0
1
2.662
2.767
2.873
3.176
3.282
3.388
V
1
0
1
1
0
2.574
2.676
2.778
3.071
3.173
3.276
V
1
0
1
1
1
2.486
2.584
2.683
2.966
3.065
3.164
V
1
1
0
0
0
2.398
2.493
2.588
2.861
2.956
3.052
V
1
1
0
0
1
2.310
2.401
2.493
2.756
2.848
2.940
V
1
1
0
1
0
2.222
2.310
2.398
2.651
2.739
2.828
V
1
1
0
1
1
2.134
2.218
2.303
2.546
2.631
2.716
V
1
1
1
0
0
2.046
2.127
2.208
2.441
2.522
2.604
V
1
1
1
0
1
1.958
2.035
2.113
2.336
2.414
2.492
V
1
1
1
1
0
1.870
1.944
2.018
2.231
2.305
2.380
V
0
0
0
0
0
1.826
1.898
1.971
2.178
2.251
2.324
V
0
0
0
0
1
1.782
1.8520
1.923
2.126
2.197
2.268
V
0
0
0
1
0
1.738
1.807
1.876
2.073
2.142
2.212
V
0
0
0
1
1
1.694
1.761
1.828
2.021
2.088
2.156
V
0
0
1
0
0
1.650
1.715
1.781
1.968
2.034
2.100
V
0
0
1
0
1
1.606
1.669
1.733
1.916
1.980
2.044
V
0
0
1
1
0
1.562
1.624
1.686
1.863
1.925
1.988
V
0
0
1
1
1
1.518
1.578
1.638
1.811
1.871
1.932
V
0
1
0
0
0
1.474
1.532
1.591
1.758
1.817
1.876
V
0
1
0
0
1
1.430
1.486
1.543
1.706
1.763
1.820
V
0
1
0
1
0
1.386
1.441
1.496
1.653
1.708
1.764
V
0
1
0
1
1
1.342
1.395
1.448
1.601
1.654
1.708
V
0
1
1
0
0
1.298
1.349
1.401
1.548
1.600
1.652
V
0
1
1
0
1
1.254
1.303
1.353
1.496
1.546
1.596
V
0
1
1
1
0
1.210
1.258
1.306
1.443
1.491
1.540
V
0
1
1
1
1
1.166
1.212
1.258
1.391
1.437
1.484
V
1
1
1
1
1
1.094
1.138
1.181
1.306
1.349
1.393
V
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CS5166
PACKAGE PIN DESCRIPTION
PACKAGE PIN #
SO−16L
PIN SYMBOL
FUNCTION
1, 2, 3, 4, 6
VID0−VID4
Voltage ID DAC input pins. These pins are internally pulled up to 5.0 V if left open. VID4
selects the DAC range. When VID4 is high (logic one), the Error Amp reference range is
2.125 V to 3.525 V with 100 mV increments. When VID4 is low (logic zero), the Error
Amp reference voltage is 1.325 V to 2.075 V with 50 mV increments.
5
SS
Soft Start Pin. A capacitor from this pin to LGND sets the Soft Start and fault timing.
7
COFF
Off−Time Capacitor Pin. A capacitor from this pin to LGND sets both the normal and
extended off time.
8
ISENSE
9
VCC
10
GATE(H)
11
PGND
12
GATE(L)
Low Side Synchronous FET driver pin.
13
PWRGD
Power Good Output. Open collector output drives low when VFB is out of regulation.
14
LGND
Reference ground. All control circuits are referenced to this pin.
15
COMP
Error Amp output. PWM Comparator reference input. A capacitor to LGND provides Error
Amp compensation.
16
VFB
Error Amp, PWM Comparator feedback input, Current Sense Comparator Non−Inverting
input, and PWRGD Comparator input.
Current Sense Comparator Inverting Input.
Input Power Supply Pin.
High Side Switch FET driver pin.
High current ground for the GATE(H) and GATE(L) pins.
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CS5166
−
VCC Monitor
VCC
+
3.95 V
3.87V
VGATE(H)
5.0 V
−
SS Low
Comparator
+
60 μA
0.7 V
SS
+
2.0 μA
Error Amplifier
VID1
+
5 BIT
DAC
VID2
S
Q
FAULT
FAULT
PGND
FAULT
Latch
SS High
Comparator
VCC
−
VCC1
VGATE(L)
−
VID4
PGND
PWM
Comparator
VID3
−
PWM COMP
+
Blanking
VCC
−8.5%
Maximum
On−Time
Timeout
+8.5%
+
−
−
+
76 mV
Extended
Off−Time
Timeout
+
65 μs
Delay
R
Q
S
Q
PWM
Latch
Normal
Off−Time
30 μA
−
Off−Time
Timeout
GATE(H) = ON
GATE(H) = OFF
COFF
One Shot
R
S
ISENSE
Comparator
VFB
Time−Out
Timer
−
+
ISENSE
LGND
Q
2.5 V
COMP
VID0
PWRGD
R
1.0 V
VFB Low
Comparator
Figure 2. Block Diagram
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Edge Triggered
COFF
Q
CS5166
TYPICAL PERFORMANCE CHARACTERISTICS
180
160
160
140
140
Risetime (ns)
200
180
120
120
100
100
80
60
60
VCC = 12 V
40
0
2000 4000
TA = 25°C
20
0
6000 8000 10000 12000 14000 16000
0
2000 4000
Load Capacitance (pF)
Load Capacitance (pF)
Figure 3. GATE(L) Risetime vs. Load Capacitance
Figure 4. GATE(H) Risetime vs. Load Capacitance
0.04
200
DAC Output Voltage Deviation (%)
180
160
120
100
80
VCC = 12 V
TA = 25°C
−0.08
−0.1
6000 8000 10000 12000 14000 16000
0
20
Load Capacitance (pF)
0.04
0.05
0.02
0
−0.10
2.125
2.075
2.025
1.975
1.925
1.875
1.825
1.725
1.775
1.675
1.625
−0.25
1.575
−0.10
1.525
−0.20
DAC Output Voltage Setting (V)
DAC Output Voltage Setting (V)
Figure 7. Percent Output Error vs. DAC Voltage
Setting, VCC = 12 V, TA = 255C, VID4 = 0
Figure 8. Percent Output Error vs. DAC Output
Voltage Setting VCC = 12 V, TA = 255C, VID4 = 1
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3.525
−0.15
−0.08
1.425
120
3.425
−0.06
1.475
100
3.325
−0.04
1.325
80
−0.05
2.425
−0.02
2.325
Output Error (%)
0
1.375
60
Figure 6. DAC Output Voltage vs. Temperature,
DAC Code = 10111, VCC = 12 V
2.225
Figure 5. GATE(H) & GATE(L) Falltime vs. Load
Capacitance
Output Error (%)
40
Junction Temperature (°C)
3.225
2000 4000
−0.06
3.125
0
−0.04
3.025
20
−0.02
2.925
40
0
2.825
60
0.02
2.525
Falltime (ns)
140
0
6000 8000 10000 12000 14000 16000
2.725
0
VCC = 12 V
40
TA = 25°C
20
80
2.625
Risetime (ns)
200
CS5166
APPLICATIONS INFORMATION
THEORY OF OPERATION
since the error amplifier bandwidth can be rolled off at a low
frequency. Enhanced noise immunity improves remote
sensing of the output voltage, since the noise associated with
long feedback traces can be effectively filtered.
The Bode plot in Figure 10 shows the gain and phase
margin of the CS5166 single pole feedback loop and
demonstrates the overall stability of the CS5166−based
regulator.
V2 Control Method
The V2 method of control uses a ramp signal that is
generated by the ESR of the output capacitors. This ramp is
proportional to the AC current through the main inductor
and is offset by the value of the DC output voltage. This
control scheme inherently compensates for variation in
either line or load conditions, since the ramp signal is
generated from the output voltage itself. This control
scheme differs from traditional techniques such as voltage
mode, which generates an artificial ramp, and current mode,
which generates a ramp from inductor current.
PWM
Comparator
GATE(H)
C
GATE(L)
−
+
Ramp
Signal
VFB
Error
Amplifier
COMP
Error
Signal
V2
Figure 10. Feedback Loop Bode Plot
Line and load regulation are drastically improved because
there are two independent voltage loops. A voltage mode
controller relies on a change in the error signal to
compensate for a deviation in either line or load voltage.
This change in the error signal causes the output voltage to
change corresponding to the gain of the error amplifier,
which is normally specified as line and load regulation.
A current mode controller maintains fixed error signal
under deviation in the line voltage, since the slope of the
ramp signal changes, but still relies on a change in the error
signal for a deviation in load. The V2 method of control
maintains a fixed error signal for both line and load
variation, since the ramp signal is affected by both line and
load.
−
E
+
Reference
Voltage
Figure 9. V2 Control Diagram
The
control method is illustrated in Figure 9. The
output voltage is used to generate both the error signal and
the ramp signal. Since the ramp signal is simply the output
voltage, it is affected by any change in the output regardless
of the origin of that change. The ramp signal also contains
the DC portion of the output voltage, which allows the
control circuit to drive the main switch to 0% or 100% duty
cycle as required.
A change in line voltage changes the current ramp in the
inductor, affecting the ramp signal, which causes the V2
control scheme to compensate the duty cycle. Since the
change in inductor current modifies the ramp signal, as in
current mode control, the V2 control scheme has the same
advantages in line transient response.
A change in load current will have an affect on the output
voltage, altering the ramp signal. A load step immediately
changes the state of the comparator output, which controls
the main switch. Load transient response is determined only
by the comparator response time and the transition speed of
the main switch. The reaction time to an output load step has
no relation to the crossover frequency of the error signal
loop, as in traditional control methods.
The error signal loop can have a low crossover frequency,
since transient response is handled by the ramp signal loop.
The main purpose of this ‘slow’ feedback loop is to provide
DC accuracy. Noise immunity is significantly improved,
Constant Off Time
To maximize transient response, the CS5166 uses a
constant off time method to control the rate of output pulses.
During normal operation, the off time of the high side switch
is terminated after a fixed period, set by the COFF capacitor.
To maintain regulation, the V2 control loop varies switch on
time. The PWM comparator monitors the output voltage
ramp, and terminates the switch on time.
Constant off time provides a number of advantages.
Switch duty cycle can be adjusted from 0 to 100% on a pulse
by pulse basis when responding to transient conditions. Both
0% and 100% duty cycle operation can be maintained for
extended periods of time in response to load or line
transients. PWM slope compensation to avoid
sub−harmonic oscillations at high duty cycles is avoided.
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CS5166
Switch on time is limited by an internal 30 μs (typical)
timer, minimizing stress to the power components.
Programmable Output
The CS5166 is designed to provide two methods for
programming the output voltage of the power supply. A five
bit on board digital to analog converter (DAC) is used to
program the output voltage within two different ranges. The
first range is 2.125 V to 3.525 V in 100 mV steps, the second
is 1.325 V to 2.075 V in 50 mV steps, depending on the
digital input code. If all five bits are left open, the CS5166
enters adjust mode. In adjust mode, the designer can choose
any output voltage by using resistor divider feedback to the
VFB pin, as in traditional controllers. The CS5166 is
specifically designed to meet or exceed Intel’s Pentium II
specifications.
M 250 μs
Trace 1− Regulator Output Voltage (1.0 V/div.)
Trace 2− Inductor Switching Node (2.0 V/div.)
Trace 3− 12 V Input (VCC) (5.0 V/div.)
Trace 4− 5.0 V Input (1.0 V/div.)
Figure 11. Demonstration Board Startup in Response
to Increasing 12 V and 5.0 V Input Voltages. Extended
Off Time is Followed by Normal Off Time Operation
when Output Voltage Achieves Regulation to the Error
Amplifier Output.
Start Up
Until the voltage on the VCC supply pin exceeds the 3.95 V
monitor threshold, the Soft Start and GATE pins are held
low. The FAULT latch is reset (no Fault condition). The
output of the error amplifier (COMP) is pulled up to 1.0 V by
the comparator clamp. When the VCC pin exceeds the
monitor threshold, the GATE(H) output is activated, and the
Soft Start capacitor begins charging. The GATE(H) output
will remain on, enabling the NFET switch, until terminated
by either the PWM comparator, or the maximum on time
timer.
If the maximum on time is exceeded before the regulator
output voltage achieves the 1.0 V level, the pulse is
terminated. The GATE(H) pin drives low, and the GATE(L)
pin drives high for the duration of the extended off time. This
time is set by the time out timer and is approximately equal
to the maximum on time, resulting in a 50% duty cycle. The
GATE(L) pin will then drive low, the GATE(H) pin will
drive high, and the cycle repeats.
When regulator output voltage achieves the 1.0 V level
present at the COMP pin, regulation has been achieved and
normal off time will ensue. The PWM comparator
terminates the switch on time, with off time set by the COFF
capacitor. The V2 control loop will adjust switch duty cycle
as required to ensure the regulator output voltage tracks the
output of the error amplifier.
The Soft Start and COMP capacitors will charge to their
final levels, providing a controlled turn on of the regulator
output. Regulator turn on time is determined by the COMP
capacitor charging to its final value. Its voltage is limited by
the Soft Start COMP clamp and the voltage on the Soft Start
pin.
Trace 1− Regulator Output Voltage (1.0 V/div.)
Trace 3− COMP PIn (error amplifier output) (1.0 V/div.)
Trace 4− Soft Start Pin (2.0 V/div.)
Figure 12. Demonstration Board Startup Waveforms
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CS5166
M 10.0 μs
Trace 1− GATE(H) (10 V/div.)
Trace 2− Inductor Switching Node (5.0 V/div.)
Trace 3− Output Inductor Ripple Current (2.0 A/div.)
Trace 4− VOUT ripple (20 mV/div.)
Trace 1− Regulator Output Voltage (5.0 V/div.)
Trace 2− Inductor Switching Node (5.0 V/div.)
Figure 13. Demonstration Board Enable Startup
Waveforms
Figure 15. Normal Operation Showing
Output Inductor Ripple Current and Output
Voltage Ripple, ILOAD = 14 A, VOUT = +2.825 V
(DAC = 10111)
Normal Operation
During normal operation, switch off time is constant and
set by the COFF capacitor. Switch on time is adjusted by the
V2 control loop to maintain regulation. This results in
changes in regulator switching frequency, duty cycle, and
output ripple in response to changes in load and line. Output
voltage ripple will be determined by inductor ripple current
working and the ESR of the output capacitors (see Figures
14 and 15).
Transient Response
The CS5166 V2 control loop’s 150 ns reaction time
provides unprecedented transient response to changes in
input voltage or output current. Pulse by pulse adjustment of
duty cycle is provided to quickly ramp the inductor current
to the required level. Since the inductor current cannot be
changed instantaneously, regulation is maintained by the
output capacitor(s) during the time required to slew the
inductor current.
Overall load transient response is further improved
through a feature called “Adaptive Voltage Positioning”.
This technique pre−positions the output capacitors voltage
to reduce total output voltage excursions during changes in
load.
Holding tolerance to 1.0% allows the error amplifiers
reference voltage to be targeted +25 mV high without
compromising DC accuracy. A “Droop Resistor”,
implemented through a PC board trace, connects the Error
Amps feedback pin (VFB) to the output capacitors and load
and carries the output current. With no load, there is no DC
drop across this resistor, producing an output voltage
tracking the Error amps, including the +25 mV offset. When
the full load current is delivered, an 50 mV drop is developed
across this resistor. This results in output voltage being
offset −25 mV low.
The result of Adaptive Voltage Positioning is that
additional margin is provided for a load transient before
Trace 1− GATE(H) (10 V/div.)
Trace 2− Inductor Switching Node (5.0 V/div.)
Trace 3− Output Inductor Ripple Current (2.0 A/div.)
Trace 4− VOUT ripple (20 mV/div.)
Figure 14. Normal Operation Showing Output
Inductor Ripple Current and Output Voltage
Ripple, 0.5 A Load, VOUT = +2.825 V (DAC = 10111)
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CS5166
reaching the output voltage specification limits. When load
current suddenly increases from its minimum level, the
output capacitor is pre−positioned +25 mV. Conversely,
when load current suddenly decreases from its maximum
level, the output capacitor is pre−positioned −25 mV (see
Figures 16, 17, and 18). For best Transient Response, a
combination of a number of high frequency and bulk output
capacitors are usually used.
If the Maximum On−Time is exceeded while responding
to a sudden increase in Load current, a normal off−time
occurs to prevent saturation of the output inductor.
Trace 1− GATE(H) (10 V/div.)
Trace 2− Inductor Switching Node (5.0 V/div.)
Trace 3− Load Current (5.0 A/div)
Trace 4− VOUT (100 mV/div.)
Figure 18. Output Voltage Transient Response to a
14 A Load Turn−Off, VOUT = +2.825 V (DAC = 10111)
Power Supply Sequencing
The CS5166 offers inherent protection from undefined
start up conditions, regardless of the 12 V and 5.0 V supply
power up sequencing. The turn on slew rates of the 12 V and
5.0 V power supplies can be varied over wide ranges without
affecting the output voltage or causing detrimental effects to
the buck regulator.
Trace 3− Load Current (5.0 A/10 mV/div.)
Trace 4− VOUT (100 mV/div.)
PROTECTION AND MONITORING FEATURES
Figure 16. Output Voltage Transient Response to
a 14 A Load Pulse, VOUT = +2.825 V (DAC = 10111)
Overcurrent Protection
A loss−less hiccup mode current limit protection feature
is provided, requiring only the Soft Start capacitor to
implement. The CS5166 provides overcurrent protection by
sensing the current through a “Droop” resistor, using an
internal current sense comparator. The comparator
compares this voltage drop to an internal reference voltage
of 76 mV (typical).
If the voltage drop across the “Droop” resistor exceeds
this threshold, the current sense comparator allows the fault
latch to be set. This causes the regulator to stop switching.
During this overcurrent condition, the CS5166 stays off for
the time it takes the Soft Start capacitor to slowly discharge
by a 2.0 μA current source until it reaches its lower 0.7 V
threshold.
At that time the regulator attempts to restart normally by
delivering short gate pulses to both FET’s. The CS5166 will
operate initially in its extended off time mode with a 50%
duty cycle, while the Soft Start capacitor is charged with a
60 mA charge current. The gates will switch on while the
Trace 1− GATE(H) (10 V/div.)
Trace 2− Inductor Switching Node (5.0 V/div.)
Trace 3− Load Current (5.0 A/div)
Trace 4− VOUT (100 mV/div.)
Figure 17. Output Voltage Transient Response to a
14 A Load Step, VOUT = +2.825 V (DAC = 10111)
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CS5166
Soft Start capacitor is charged to its upper 2.7 V threshold.
During an overload condition the Soft Start
charge/discharge current ratio sets the duty cycle for the
pulses (2.0 μA/60 μA = 3.3%), while actual duty cycle is half
that due to the extended off time mode (1.65%) when VFB
is less than 1.0 V. The Soft Start hiccup pulses last for a 3.0
ms period at the end of which the duty cycle repeats if a fault
is detected, otherwise normal operation resumes.
The protection scheme minimizes thermal stress to the
regulator components, input power supply, and PC board
traces, as the overcurrent condition persists. Upon removal
of the overload, the fault latch is cleared, allowing normal
operation to resume. The current limit trip point can be
adjusted through an external resistor, providing the user with
the current limit set−point flexibility.
MOSFET to shut off, disconnecting the regulator from it’s
input voltage. The bottom MOSFET is then activated,
resulting in a “crowbar” action to clamp the output voltage
and prevent damage to the load (see Figures 21 and 22 ). The
regulator will remain in this state until the overvoltage
condition ceases or the input voltage is pulled low. The
bottom FET and board trace must be properly designed to
implement the OVP function. If a dedicated OVP output is
required, it can be implemented using the circuit in Figure
23. In this figure the OVP signal will go high (overvoltage
condition), if the output voltage (VCORE) exceeds 20% of
the voltage set by the particular DAC code and provided that
PWRGD is low. It is also required that the overvoltage
condition be present for at least the PWRGD delay time for
the OVP signal to be activated. The resistor values shown in
Figure 23 are for VDAC = +2.8 V (DAC = 10111). The VOVP
(overvoltage trip−point) can be set using the following
equation:
ǒ
VOVP + VBEQ3 1 ) R2
R1
Ǔ
M 25.0 ms
Trace 4− 5.0 V Supply Voltage (2.0 V/div.)
Trace 3− Soft Start Timing Capacitor (1.0 V/div.)
Trace 2− Inductor Switching Node (2.0 V/div.)
Figure 19. Demonstration Board Hiccup Mode Short
Circuit Protection. Gate Pulses are Delivered While
the Soft Start Capacitor Charges, and Cease During
Discharge
M 10.0 μs
Trace 4− 5.0 V from PC Power Supply (5.0 V/div.)
Trace 1− Regulator Output Voltage (1.0 V/div.)
Trace 2− Inductor Switching Node 5.0 V/div.)
Figure 21. OVP Response to an Input−to−Output
Short Circuit by Immediately Providing 0% Duty
Cycle, Crow−Barring the Input Voltage to Ground
M 50.0 μs
Trace 4− 5.0 V from PC Power Supply (2.0 V/div.)
Trace 2− Inductor Switching Node (2.0 V/div.)
Figure 20. Demonstration Board Startup with
Regulator Output Shorted To Ground
M 5.00 ms
Overvoltage Protection
Trace 4− 5.0 V from PC Power Supply (2.0 V/div.)
Overvoltage protection (OVP) is provided as result of the
normal operation of the V2 control topology and requires no
additional external components. The control loop responds
to an overvoltage condition within 100 ns, causing the top
Trace 1− Regulator Output Voltage (1.0 V/div.)
Figure 22. OVP Response to an Input−to−Output Short
Circuit by Pulling the Input Voltage to Ground
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CS5166
VCORE
15 k
+5.0 V
56 k
R1
R2
Q3
2N3906
5.0 k
OVP
20 k
+5.0 V
CS5166
10 k
PWRGD
10 k
Q2
2N3904
10 K
Q1
2N3906
Figure 23. Circuit To Implement A Dedicated OVP
Output Using The CS5166
Trace 2− PWRGD (2.0 V/div.)
Trace 4− VFB (1.0 V/div.)
Figure 25. Power Good Response to an Out of
Regulation Condition
Power Good Circuit
The Power Good pin (pin 13) is an open−collector signal
consistent with TTL DC specifications. It is externally
pulled−up, and is pulled low (below 0.3 V) when the
regulator output voltage typically exceeds ± 8.5% of the
nominal output voltage. Maximum output voltage deviation
before Power Good is pulled low is ± 12%.
Figure 25 shows the relationship between the regulated
output voltage VFB and the Power Good signal. To prevent
Power Good from interrupting the CPU unnecessarily, the
CS5166 has a built−in delay to prevent noise at the VFB pin
from toggling Power Good. The internal time delay is
designed to take about 75 μs for Power Good to go low and
65 μs for it to recover. This allows the Power Good signal to
be completely insensitive to out of regulation conditions that
are present for a duration less than the built in delay (see
Figure 26).
It is therefore required that the output voltage attains an out
of regulation or in regulation level for at least the built−in delay
time duration before the Power Good signal can change state.
Trace 2− PWRGD (2.0 V/div.)
Trace 4− VOUT (1.0 V/div.)
Figure 24. PWRGD Signal Becomes Logic High as
VOUT Enters −8.5% of Lower PWRGD Threshold,
VOUT = +2.825 V (DAC = 10111)
Trace 2− PWRGD (2.0 V/div.)
Trace 4− VFB (1.0 V/div.)
Figure 26. Power Good is Insensitive to Out of
Regulation Conditions that are Present for a
Duration Less Than the Built In Delay
External Output Enable Circuit
On/off control of the regulator can be implemented
through the addition of two additional discrete components
(see Figure ). This circuit operates by pulling the Soft Start
pin high, and the ISENSE pin low, emulating a current limit
condition.
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CS5166
5.0 V
MMUN2111T1 (SOT−23)
5
8
SS
CS5166
ISENSE
IN4148
Shutdown
Input
Trace 3− GATE(H) (10 V/div.)
Trace 1− GATE(H) − 5.0 VIN
Figure 27. Implementing Shutdown with the CS5166
Trace 4− GATE(L) (10 V/div.)
Trace 2− Inductor Switching Node (5.0 V/div.)
Selecting External Components
Figure 28. Gate Drive Waveforms Depicting
Rail to Rail Swing
The CS5166 buck regulator can be used with a wide range
of external power components to optimize the cost and
performance of a particular design. The following
information can be used as general guidelines to assist in
their selection.
NFET Power Transistors
Both logic level and standard FETs can be used. The
reference designs derive gate drive from the 12 V supply
which is generally available in most computer systems and
utilize logic level FETs. A charge pump may be easily
implemented to support 5.0 V only systems. Multiple
FET’s may be paralleled to reduce losses and improve
efficiency and thermal management.
Voltage applied to the FET gates depends on the
application circuit used. Both upper and lower gate driver
outputs are specified to drive to within 1.5 V of ground when
in the low state and to within 2.0 V of their respective bias
supplies when in the high state. In practice, the FET gates
will be driven rail to rail due to overshoot caused by the
capacitive load they present to the controller IC. For the
typical application where VCC = 12 V and 5.0 V is used as
the source for the regulator output current, the following
gate drive is provided:
Trace 1 = GATE(H) (5.0 V/div.)
Trace 2 = GATE(L) (5.0 V/div.)
Figure 29. Normal Operation Showing the Guaranteed
Non−Overlap Time Between the High and Low−Side
MOSFET Gate Drives, ILOAD = 14 A
The CS5166 provides adaptive control of the external
NFET conduction times by guaranteeing a typical 65 ns
non−overlap (as seen in Figure 29) between the upper and
lower MOSFET gate drive pulses. This feature eliminates
the potentially catastrophic effect of “shoot−through
current”, a condition during which both FETs conduct
causing them to overheat, self−destruct, and possibly inflict
irreversible damage to the processor.
The most important aspect of FET performance is
RDSON, which effects regulator efficiency and FET thermal
management requirements.
The power dissipated by the MOSFETs may be estimated
as follows:
Switching MOSFET:
VGS(TOP) + 12 V * 5.0 V + 7.0 V
VGS(BOTTOM) + 12 V
(see Figure 28)
Power + ILOAD2
RDSON
duty cycle
Synchronous MOSFET:
Power + ILOAD2
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RDSON
(1 * duty cycle)
CS5166
Duty Cycle =
VOUT ) (ILOAD
ƪ
1.35 * 1.15 + 16%
1.25
RDSON OF SYNCH FET)
VIN)(ILOAD RDSON OF SYNCH FET)
* (ILOAD RDSON OF SWITCH FET)
2. Mismatch due to L/W. The variation in L/W is
governed by variations due to the PCB manufacturing
process that affect the geometry and the power
dissipation capability of the droop resistor. The error
due to L/W mismatch is typically 1.0%.
3. Thermal Considerations. Due to I2 × R power losses
the surface temperature of the droop resistor will
increase causing the resistance to increase. Also, the
ambient temperature variation will contribute to the
increase of the resistance, according to the formula:
ƫ
Off Time Capacitor (COFF)
The COFF timing capacitor sets the regulator off time:
TOFF + COFF
4848.5
The preceding equations for duty cycle can also be used
to calculate the regulator switching frequency and select the
COFF timing capacitor:
COFF +
Perioid
R + R20[1 ) a20(T * 20)]
(1 * duty cycle)
4848.5
where:
R20 = resistance at 20°C
where:
Period +
a + 0.00393
°C
1
switching frequency
T = operating temperature
R = desired droop resistor value
For temperature T = 50°C, the % R change = 12%
Schottky Diode for Synchronous FET
For synchronous operation, a Schottky diode may be
placed in parallel with the synchronous FET to conduct the
inductor current upon turn off of the switching FET to
improve efficiency. The CS5166 reference circuit does not
use this device due to it’s excellent design. Instead, the
body diode of the synchronous FET is utilized to reduce
cost and conducts the inductor current. For a design
operating at 200 kHz or so, the low non−overlap time
combined with Schottky forward recovery time may make
the benefits of this device not worth the additional expense.
The power dissipation in the synchronous MOSFET due to
body diode conduction can be estimated by the following
equation:
Power + VBD
ILOAD
conduction time
Droop Resistor Tolerance
Tolerance due to sheet resistivity variation
Tolerance due to L/W error
Tolerance due to temperature variation
Total tolerance for droop resistor
In order to determine the droop resistor value the nominal
voltage drop across it at full load has to be calculated. This
voltage drop has to be such that the output voltage full load
is above the minimum DC tolerance spec.
[VDAC(MIN) * VDC(MIN)]
VDROOP(TYP) +
1 ) RDROOP(TOLERANCE)
switching frequency
Example: for a 300 MHz Pentium II, the DC accuracy spec
is 2.74 < VCC(CORE) < 2.9 V, and the AC accuracy spec is
2.67 V < VCC(CORE) < 2.93 V. The CS5166 DAC output
voltage is +2.796 V < VDAC < +2.853 V. In order not to
exceed the DC accuracy spec, the voltage drop developed
across the resistor must be calculated as follows:
Where VBD = the forward drop of the MOSFET body
diode. For the CS5166 demonstration board:
Power + 1.6 V
14.2 A
100 ns
16%
1.0%
12%
29%
200 kHz + 0.45 W
This is only 1.1% of the 40 W being delivered to the load.
“Droop” Resistor for Adaptive Voltage Positioning
VDROOP(TYP) +
Adaptive voltage positioning is used to help keep the
output voltage within specification during load transients.
To implement adaptive voltage positioning a “Droop
Resistor” must be connected between the output inductor
and output capacitors and load. This resistor carries the full
load current and should be chosen so that both DC and AC
tolerance limits are met. An embedded PC trace resistor has
the distinct advantage of near zero cost implementation.
However, this droop resistor can vary due to three reasons:
1) the sheet resistivity variation causes the thickness of the
PCB layer to vary. 2) the mismatch of L/W, and 3)
temperature variation.
1. Sheet Resistivity for one ounce copper, the thickness
variation typically 1.15 mil to 1.35 mil. Therefore the
error due to sheet resistivity is:
[VDAC(MIN) * VDC PENTIUMII(MIN)]
1 ) RDROOP(TOLERANCE)
+ 2.796 V * 2.74 V + 43 mV
1.3
With the CS5166 DAC accuracy being 1.0%, the internal
error amplifier’s reference voltage is trimmed so that the
output voltage will be 25 mV high at no load. With no load,
there is no DC drop across the resistor, producing an output
voltage tracking the error amplifier output voltage,
including the offset. When the full load current is delivered,
a drop of −43 mV is developed across the resistor. Therefore,
the regulator output is pre−positioned at 25 mV above the
nominal output voltage before a load turn−on. The total
voltage drop due to a load step is ΔV−25 mV and the
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CS5166
deviation from the nominal output voltage is 25 mV smaller
than it would be if there was no droop resistor. Similarly at
full load the regulator output is pre−positioned at 18 mV
below the nominal voltage before a load turn−off. The total
voltage increase due to a load turn−off is ΔV−18 mV and the
deviation from the nominal output voltage is 18 mV smaller
than it would be if there was no droop resistor. This is
because the output capacitors are pre−charged to value that
is either 25 mV above the nominal output voltage before a
load turn−on or, 18 mV below the nominal output voltage
before a load turn−off (see Figure 16).
Obviously, the larger the voltage drop across the droop
resistor (the larger the resistance), the worse the DC and load
regulation, but the better the AC transient response.
VIN
CS5166
IFB
RFB
Current Limit Comparator
VFB
Q1
L
RDROOP
Q2
+
ISENSE
−
VOUT
COUT
VTH
ISENSE
RISENSE
ISENSE
Figure 30. Circuit Used to Determine the Voltage Across the Droop Resistor that will Trip the
Internal Current Sense Comparator
Current Limit Setpoint Calculations
We calculate the range of load currents that will cause the
internal current sense comparator to detect and overload
condition.
From the overcurrent detection data section on page 3.
Nominal Current Limit Setpoint
The following is the design equations used to set the
current limit trip point by determining the value of the
embedded PCB trace used as a current sensing element.
The current limit setpoint has to be higher than the normal
full load current. Attention has to be paid to the current rating
of the external power components as these are the first to fail
during an overload condition. The MOSFET continuous and
pulsed drain current rating at a given case temperature has
to be accounted for when setting the current limit trip point.
For example the IRL 3103S (D2 PAK) MOSFET has a
continuous drain current rating of 45 A at VGS = 10 V and
TC = 100°C. Temperature curves on MOSFET
manufacturers’ data sheets allow the designer to determine
the MOSFET drain current at a particular VGS and TJ
(junction temperature). This, in turn, will assist the designer
to set a proper current limit, without causing device
breakdown during an overload condition.
For 300 MHz Pentium II CPU the full load is 14.2 A. The
internal current sense comparator current limit voltage
limits are: 55 mV < VTH < 130 mV. Also, there is a 29% total
variation in RSENSE as discussed in the previous section.
We select the value of the current sensing element
(embedded PCB trace) for the minimum current limit
setpoint:
VTH(MIN)
RSENSE(MAX) +
å RSENSE
ICL(MIN)
RSENSE
VTH(TYP) + 76 mV
ICL(NOM) +
VTH(TYP)
RSENSE(NOM)
Maximum Current Limit Setpoint
Therefore, ICL(NOM) + 76 mV + 25.3
3.0 mW
VTH(MAX) + 110 mV
Therefore,
ICL(MAX) +
110 mV
110 mV
110 mV
+
+
+ 51.6 A
3.0 mW 0.71
RSENSE(MIN)
RSENSE 0.71
Therefore, the range of load currents that will cause the
internal current sense comparator to detect an overload
condition through a 3.0 mΩ embedded PCB trace is: 14.2 A
< ICL < 51.6 A, with 25.3 A being the nominal overload
condition.
There may be applications whose layout will require the
use of two extra filter components, a 510 Ω resistor in series
with the ISENSE pin, and a 0.1 μF capacitor between the
ISENSE and VFB pins. These are needed for proper current
limit operation and the resistor value is layout dependent.
1.29 + 55 mV å
14.2 A
1.29 + 3.87 mW å RSENSE + 3.0 mW
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CS5166
This series resistor affects the calculation of the current
limit setpoint, and has to be taken into account when
determining an effective current limit.
The calculations below show how the current limit
setpoint is determined when this 510 Ω is taken into
consideration.
VTRIP + VTH ) (ISENSE
RISENSE) * (RFB
ICL(NOM) +
Therefore,
ICL(NOM) + 90.97 mV + 28.6 A
3.18 mW
Maximum Current Limit Setpoint
IFB)
ICL(MAX) +
Where:
VTRIP = voltage across the droop resistor that trips the
ISENSE comparator.
VTH = internal ISENSE comparator threshold
ISENSE = ISENSE bias current
RISENSE = ISENSE pin 510 Ω filter resistor
RFB = VFB pin 3.3 k filter resistor
IFB = VFB bias current
Minimum current sense resistor (droop resistor) voltage
drop required for current limit when RISENSE is used
VTRIP(MIN) + 55 mV ) (13 mA
510) * (3.3 k
ICL(MAX) +
1.0 mA)
Design Rules for Using a Droop Resistor
The basic equation for laying an embedded resistor is:
RAR + ò
+ 76 mV ) 15.3 mV * 0.33 mV + 90.97 mV
510)
+ 110 mV ) 25.5 mV + 135.5 mV
(W
L
t)
For most PCBs the copper thickness, t, is 35 μm (1.37
mils) for one ounce copper. ρ = 717.86 μΩ−mil
For a Pentium II load of 14.2 A the resistance needed to
create a 43 mV drop at full load is:
The value of RSENSE (current sense PCB trace) is then
calculated:
RSENSE(MAX) + 58.3 mV + 4.1 mW
14.2 A
RSENSE(NOM) +
L or R + ò
A
where:
A = W × t = cross−sectional area
ρ = the copper resistivity (μΩ − mil)
L = length (mils)
W = width (mils)
t = thickness (mils)
0.1 mA)
Maximum current sense resistor (droop resistor) voltage
drop required for current limit when RISENSE is used
VTRIP(NOM) + 110 mV ) (50 mA
135 mV
+ 60 A
3.18 mW 0.71
Therefore, the range of load currents that will cause the
internal current sense comparator to detect an overload
condition through a 3.0 mΩ embedded PCB trace is: 14.2 A
< ICL 60 A, with 28.6 A being the nominal overload
condition.
Nominal current sense resistor (droop resistor) voltage
drop required for current limit when RISENSE is used
510) * (3.3 k
VTRIP(MAX)
RSENSE(MAX)
Therefore,
+ 55 mV ) 6.6 mV * 3.3 mV + 58.3 mV
VTRIP(NOM) + 76 mV ) (30 mA
VTRIP(NOM)
RSENSE(NOM)
Response Droop + 43 mV + 43 mV + 3.0 mW
14.2 A
IOUT
RSENSE(MAX)
+ 4.1 mWm + 3.18 mW
1.29
1.29
The resistivity of the copper will drift with the
temperature according to the following guidelines:
The range of load currents that will cause the internal
current sense comparator to detect an overload condition is
as follows:
Nominal Current Limit Setpoint
DR + 12% @ TA + ) 50°C
DR + 34% @ TA + ) 100°C
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CS5166
5.0 V
1200 μF/10 V × 3
12 V
IRL3103S
1.0 μF
COFF
SS
0.1 μF
COMP
VID0
0.1 μF
CS5166
330 pF
VCC
GATE(H)
1.2 μH
3.0 mΩ
510
ISENSE
2.8 V/30 A
Power Supply
1200 μF/
10 V × 5
0.1 μF
IRL3103S
GATE(L)
VID1
VID2
PGND
VID3
LGND
PWRGD
3.3 k
VID4 PWRGD VFB
VID4
VID3
1000 pF
VID2
VID1
VID0
5.0 V
1200 μF/
10 V × 3
12 V
1.0 μF
IRL3103S
330 pF
CS5166
VCC
GATE(H)
COFF
SS
0.1 μF
1.2 μH
510
ISENSE
0.1 μF
COMP
VID0
VID1
VID2
3.0 mΩ
GATE(L)
IRL3103S
PGND
VID3
LGND
VID4
VFB
3.3 k
1000 pF
Figure 31. Current Sharing of a 2.8 V/30 A Power Supply Using Two CS5166 Synchronous Buck Regulators
Droop Resistor Width Calculations
W + 14.2 A + 284 mils + 0.7213 cm
0.05
The droop resistor must have the ability to handle the load
current and therefore requires a minimum width which is
calculated as follows (assume one ounce copper thickness):
Droop Resistor Length Calculation
L+
I
W + LOAD
0.05
RDROOP
ò
+ 0.0030
where:
W = minimum width (in mils) required for proper power
dissipation, and ILOAD Load Current Amps.
The Pentium II maximum load current is 14.2 A.
Therefore:
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W
284
717.86
t
1.37 + 1626 mil + 4.13 cm
CS5166
Implementing Current Sharing Using the “Droop
Resistor”
sharing accuracy will be determined solely by their
matching. To realize the benefits of current sharing, it is not
necessary to obtain perfect matching. Keeping output
currents within ± 10% is usually acceptable.
For microprocessor applications, the value of the droop
resistor must be selected to optimize adaptive voltage
positioning, current sharing, current limit and efficiency.
Current sharing is realized by simply connecting the COMP
pins of the respective buck regulators, as shown in Figure 31.
Figure 32 shows operation with no load. In this case, there
is insufficient output voltage ripple across the droop resistor
to produce complete synchronization. Duty Cycle is close to
the theoretical 56% (VOUT/VIN) resulting in a switching
frequency of approximately 275 kHz.
Figure 34 shows operation with a 30 Amp load.
Synchronization between the two regulators is now obtained
due to increased ripple voltage. Increases losses cause the V2
control loop to increase on−time to compensate. This results
in a larger duty cycle and a corresponding decrease in
switching frequency to 233 kHz.
In addition to improving load transient performance, the
CS5166 V2 control method allows the droop resistor to
provide the additional capability to easily implement current
sharing. Figure 31 shows a simplified schematic of two
current sharing synchronous buck regulators. Each buck
regulator’s droop resistor is terminated at the load. The
PWM control signal from each Error Amp is connected
together, causing the inner PWM loop to regulate to a
common voltage. Since the voltage at each resistor terminal
is the same, this configuration results in equal voltage being
applied across each matched droop resistor. The result is
equal current flowing through each buck regulator. An
additional benefit is that synchronization to a common
switching frequency tends to be achieved because each
regulator shares a common PWM ramp signal.
In practice, each buck regulator will regulate to a slightly
different output voltage due to mismatching of the PWM
comparators, slope of the PWM ramp (output voltage
ripple), and propagation delays. At light loads, the results
can be very poor current sharing. With zero output current,
some regulators may be sourcing current while others may
be sinking current.
This results in additional power dissipation and lower
efficiency than would be obtained by a single regulator. This
is usually not an issue since efficiency is most important
when a supply is fully loaded.
This effect is similar to the difference in efficiency
between synchronous and non−synchronous buck
regulators. Synchronous buck regulators have lower
efficiency at light loads because inductor current is always
continuous, flowing from the load to ground during switch
off−time through the synchronous rectifier. Under full load
conditions, the synchronous design is more efficient due to
the lower voltage drop across the synchronous rectifier.
Likewise, the efficiency of droop sharing regulators will be
lower at light loads due to the continuous current flow in the
droop resistors. Efficiency at heavy loads tends to be higher
due to reduced I2R losses.
The output current of each regulator can be calculated
from:
IN +
Trace 1 = Output voltage ripple.
Trace 2 = Buck regulator #1 inductor switching node.
Trace 3 = Buck regulator #2 inductor switching node.
Figure 32. No Load Waveforms
(VOUT(N) * VOUT)
RDROOP(N)
where: VOUT(N) and RDROOP(N) are the output voltage
and droop resistance of a particular regulator and VOUT is
the system output voltage. Output current is the sum of each
regulator’s current:
IOUT + I1 ) I2 ) AAA ) IN
Current sharing improves with increasing load current.
The increasing voltage drop across the droop resistor due to
increasing load current eventually swamps out the
differences in regulator output voltages. If a large enough
voltage can be developed across the droop resistors, current
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CS5166
Inductor Ripple Current
Ripple Current +
[(VIN * VOUT) VOUT]
(Switching Frequency L VIN)
Example: VIN = +5.0 V, VOUT = +2.8 V, ILOAD = 14.2 A,
L = 1.2 μH, Freq = 200 kHz
Ripple Current +
[(5.0 V * 2.8 V) 2.8 V]
+ 5.1 A
[200 kHz 1.2 mH 5.0 V]
Output Ripple Voltage
VRIPPLE + Inductor Ripple Current
Output Capacitor ESR
Example:
VIN = +5.0 V, VOUT = +2.8 V, ILOAD = 14.2 A, L = 1.2 μH,
Switching Frequency = 200 kHz
Output Ripple Voltage = 5.1 A × Output Capacitor ESR
(from manufacturer’s specs)
ESR of Output Capacitors to limit Output Voltage Spikes
Trace 1 = Output voltage ripple.
Trace 2 = Buck regulator #1 inductor switching node.
Trace 3 = Buck regulator #2 inductor switching node.
Figure 33. 15 A Load Transient Waveforms
ESR +
DVOUT
DIOUT
This applies for current spikes that are faster than
regulator response time. Printed Circuit Board resistance
will add to the ESR of the output capacitors.
In order to limit spikes to 100 mV for a 14.2 A Load Step,
ESR = 0.1/14.2 = 0.007 Ω
Inductor Peak Current
Peak Current + Maximum Load Current )
ǒRipple 2CurrentǓ
Example: VIN = +5.0 V, VOUT = +2.8 V, ILOAD = 14.2 A,
L = 1.2 μH, Freq = 200 kHz
Trace 1 = Output voltage ripple.
Trace 2 = Buck regulator #1 inductor switching node.
Peak Current + 14.2 A ) (5.1ń2) + 16.75 A
Trace 3 = Buck regulator #2 inductor switching node.
A key consideration is that the inductor must be able to
deliver the Peak Current at the switching frequency without
saturating.
Figure 34. 30 A Load Waveforms
Figure 33 shows supply response to a 15 A load step with
a 30 A/μs slew rate. The V2 control loop immediately forces
the duty cycle to 100%, ramping the current in both
inductors up. A voltage spike of 136 mV due to output
capacitor impedance occurs. The inductive component of
the spike due to ESL recovers within several microseconds.
The resistive component due to ESR decreases as inductor
current replaces capacitor current.
The benefit of adaptive voltage positioning in reducing
the voltage spike can readily be seen. The difference in DC
voltage and duty cycle can also be observed. This particular
transient occurred near the beginning of regulator off time,
resulting in a longer recovery time and increased voltage
spike.
Response Time to Load Increase
(limited by Inductor value unless Maximum On−Time is
exceeded)
Response Time +
L DIOUT
(VIN * VOUT)
Example: VIN = +5.0 V, VOUT = +2.8 V, L = 1.2 μH, 14.2 A
change in Load Current
Response Time +
1.2 mH 14.2 A
+ 7.7 ms
(5.0 V * 2.8 V)
Response Time to Load Decrease
(limited by Inductor value)
Output Inductor
The inductor should be selected based on its inductance,
current capability, and DC resistance. Increasing the
inductor value will decrease output voltage ripple, but
degrade transient response.
Response Time +
L
Change in IOUT
VOUT
Example: VOUT = +2.8 V, 14.2 A change in Load Current,
L = 1.2 μH
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CS5166
Response Time +
2.0 μH
1.2 mH 14.2 A
+ 6.1 ms
2.8 V
+
Input and Output Capacitors
1200 μF × 3.0/16 V
These components must be selected and placed carefully
to yield optimal results. Capacitors should be chosen to
provide acceptable ripple on the input supply lines and
regulator output voltage. Key specifications for input
capacitors are their ripple rating, while ESR is important for
output capacitors. For best transient response, a combination
of low value/high frequency and bulk capacitors placed
close to the load will be required.
Figure 36. Input Filter
Layout Guidelines
When laying out the CPU buck regulator on a printed
circuit board, the following checklist should be used to
ensure proper operation of the CS5166.
1. Rapid changes in voltage across parasitic capacitors
and abrupt changes in current in parasitic inductors
are major concerns for a good layout.
2. Keep high currents out of sensitive ground
connections. Avoid connecting the IC GND (LGND)
between the source of the lower FET and the input
capacitor GND.
3. Avoid ground loops as they pick up noise. Use star or
single point grounding.
4. For high power buck regulators on double−sided
PCBs a single large ground plane (usually the bottom)
is recommended.
5. Even though double sided PCBs are usually sufficient
for a good layout, four−layer PCBs are the optimum
approach to reducing susceptibility to noise. Use the
two internal layers as the +5.0 V and GND planes, the
top layer for the power connections and component
vias, and the bottom layer for the noise sensitive
traces.
6. Keep the inductor switching node small by placing
the output inductor, switching and synchronous FETs
close together.
7. The FET gate traces to the IC must be as short,
straight, and wide as possible. Ideally, the IC has to be
placed right next to the FETs.
8. Use fewer, but larger output capacitors, keep the
capacitors clustered, and use multiple layer traces
with heavy copper to keep the parasitic resistance
low.
9. Place the switching FET as close to the +5.0 V input
capacitors as possible.
10. Place the output capacitors as close to the load as
possible.
11. Place the VFB filter resistor in series with theVFB pin
(pin 16) right at the pin.
12. Place the VFB filter capacitor right at the VFB pin (pin
16).
13. The “Droop” Resistor (embedded PCB trace) has to
be wide enough to carry the full load current.
14. Place the VCC bypass capacitor as close as possible to
the VCC pin and connect it to the PGND pin of the IC.
Connect the PGND pin directly to the GND plane.
THERMAL MANAGEMENT
Thermal Considerations for Power
MOSFETs and Diodes
In order to maintain good reliability, the junction
temperature of the semiconductor components should be
kept to a maximum of 150°C or lower. The thermal
impedance (junction to ambient) required to meet this
requirement can be calculated as follows:
Thermal Impedance +
TJ(MAX) * TA
Power
A heatsink may be added to TO−220 components to
reduce their thermal impedance. A number of PC board
layout techniques such as thermal vias and additional copper
foil area can be used to improve the power handling
capability of surface mount components.
EMI Management
As a consequence of large currents being turned on and off
at high frequency, switching regulators generate noise as a
consequence of their normal operation. When designing for
compliance with EMI/EMC regulations, additional
components may be added to reduce noise emissions. These
components are not required for regulator operation and
experimental results may allow them to be eliminated. The
input filter inductor may not be required because bulk filter
and bypass capacitors, as well as other loads located on the
board will tend to reduce regulator di/dt effects on the circuit
board and input power supply. Placement of the power
component to minimize routing distance will also help to
reduce emissions.
2.0 μH
33 Ω
1000 pF
Figure 35. Filter Components
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CS5166
15. Create a subground (local GND) plane preferably on
the PCB top layer and under the IC controller.
Connect all logic capacitor returns and the LGND pin
of the IC to this place. Connect the subground plane
to the main GND plane using a minimum of four (4)
vias.
+5.0 V
MBRS120
MBRS120
1.0 μF
1200 μF/10 V × 3
MBRS120
1.0 μF
VCC
VID0
VID1
VID2
VGATE(L)
1.2 μH
3.0 mΩ
COFF
SS
0.1 μF
VCC
VSS
510
ISENSE
PWRGD
VFB
LGND
1200 μF/10 V
×5
IRL3103S
PGND
COMP
0.1 μF
Droop Resistor
(Embedded PCB trace)
IRL3103S
CS5166
VID3
VID4
330 pF
VGATE(H)
0.1 μF
1000 pF
3.3 k
PWRGD
PENTIUM II
SYSTEM
VID4
VID3
VID2
VID1
VID0
Figure 37. Additional Application Diagram, +5.0 V to +2.8 V @ 14.2 A for 300 MHz Pentium II
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CS5166
PACKAGE DIMENSIONS
SO−16L
DW SUFFIX
CASE 751G−03
ISSUE B
A
D
9
1
8
NOTES:
1. DIMENSIONS ARE IN MILLIMETERS.
2. INTERPRET DIMENSIONS AND TOLERANCES
PER ASME Y14.5M, 1994.
3. DIMENSIONS D AND E DO NOT INLCUDE MOLD
PROTRUSION.
4. MAXIMUM MOLD PROTRUSION 0.15 PER SIDE.
5. DIMENSION B DOES NOT INCLUDE DAMBAR
PROTRUSION. ALLOWABLE DAMBAR
PROTRUSION SHALL BE 0.13 TOTAL IN EXCESS
OF THE B DIMENSION AT MAXIMUM MATERIAL
CONDITION.
h X 45 _
H
E
0.25
8X
M
B
M
16
q
16X
T A
M
B
B
S
B
S
e
SEATING
PLANE
A1
14X
L
A
0.25
DIM
A
A1
B
C
D
E
e
H
h
L
q
MILLIMETERS
MIN
MAX
2.35
2.65
0.10
0.25
0.35
0.49
0.23
0.32
10.15
10.45
7.40
7.60
1.27 BSC
10.05
10.55
0.25
0.75
0.50
0.90
0_
7_
C
T
PACKAGE THERMAL DATA
Parameter
SO−16L
Unit
RΘJC
Typical
23
°C/W
RΘJA
Typical
105
°C/W
V2 is a trademark of Switch Power, Inc.
Pentium is a registered trademark of Intel Corporation.
ON Semiconductor and
are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice
to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability
arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages.
“Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All
operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. SCILLC does not convey any license under its patent rights
nor the rights of others. SCILLC products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications
intended to support or sustain life, or for any other application in which the failure of the SCILLC product could create a situation where personal injury or death may occur. Should
Buyer purchase or use SCILLC products for any such unintended or unauthorized application, Buyer shall indemnify and hold SCILLC and its officers, employees, subsidiaries, affiliates,
and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death
associated with such unintended or unauthorized use, even if such claim alleges that SCILLC was negligent regarding the design or manufacture of the part. SCILLC is an Equal
Opportunity/Affirmative Action Employer. This literature is subject to all applicable copyright laws and is not for resale in any manner.
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CS5166/D