MICROSEMI NX2154ACSTR

Evaluation board available.
NX2154/2154A
300kHz SYNCHRONOUS PWM CONTROLLER
PRELIMINARY DATA SHEET
Pb Free Product
DESCRIPTION
The NX2154/2154A controller IC is a synchronous Buck
controller IC designed for step down DC to DC converter applications. It is optimized to convert bus voltages from 2V to 40V to outputs as low as 0.8V voltage.
The NX2154/2154A operates at fixed 300kHz. The
NX2154/2154A employs fixed loss-less current limiting
by sensing the Rdson of synchronous MOSFET followed
by hiccup feature.NX2154A has higher current limit
threshold than NX2154. Feedback under voltage also
triggers hiccup.
Other features of the device are: 5V gate drive, Adaptive
deadband control, Internal digital soft start, Vcc
undervoltage lock out and shutdown capability via the
comp pin.
FEATURES
n
n
n
n
n
n
Bus voltage operation from 2V to 40V
Fixed 300kHz voltage mode controller
Internal Digital Soft Start Function
Prebias Startup
Less than 50 nS adaptive deadband
Current limit triggers hiccup by sensing Rdson of
Synchronous MOSFET
n No negative spike at Vout during startup and
shutdown
n Pb-free and RoHS compliant
APPLICATIONS
n
n
n
n
n
Graphic Card on board converters
Memory Vddq Supply in mother board applications
On board DC to DC such as
5V to 3.3V, 2.5V or 1.8V
Hard Disk Drive
Set Top Box
TYPICAL APPLICATION
Vin
Vin
+5V
+33V
MBR0530T1
7
HI=SD
M3
1
BST
Comp
12nF
82pF
13.3k
6
5
Vcc
NX2154
1uF
Hdrv
50ME180WX
0.1uF
2
M1A STM6920
15uH
SW
Ldrv
Fb
1uF
Vout
+5V,3A
8
4
M1B
6ME1000WG(1000uF,30mohm)
Gnd
3
1k
191
Figure1 - Typical application of 2154
ORDERING INFORMATION
Device
NX2154CSTR
NX2154ACSTR
Rev.1.2
02/26/07
Temperature
0 to 70oC
0 to 70o C
Package
SOIC-8L
SOIC-8L
Frequency
300kHz
300kHz
OCP Threshold
360mV
540mV
Pb-Free
Yes
Yes
1
NX2154/2154A
ABSOLUTE MAXIMUM RATINGS
(NOTE1)
Vcc to GND & BST to SW voltage ................... 6.5V
BST to GND Voltage ...................................... 50V
Storage Temperature Range ............................. -65oC to 150oC
Operating Junction Temperature Range ............. -40oC to 125oC
NOTE1: Stresses above those listed in "ABSOLUTE MAXIMUM RATINGS", may cause permanent
damage to the device. This is a stress only rating and operation of the device at these or any other
conditions above those indicated in the operational sections of this specification is not implied.
PACKAGE INFORMATION
8-PIN PLASTIC SOIC (S)
θJA ≈ 130o C/W
BST 1
HDrv 2
8 SW
7 Comp
Gnd 3
6 Fb
LDrv 4
5 Vcc
ELECTRICAL SPECIFICATIONS
Unless otherwise specified, these specifications apply over Vcc = 5V, and TA = 0 to 70oC. Typical values refer to TA
= 25oC. Low duty cycle pulse testing is used which keeps junction and case temperatures equal to the ambient
temperature.
PARAMETER
Reference Voltage
Ref Voltage
Ref Voltage line regulation
Supply Voltage(Vcc)
VCC Voltage Range
VCC Supply Current (Static)
VCC Supply Current
(Dynamic)
VCC
ICC (Static) Outputs not switching
ICC
CLOAD=3300pF FS=300kHz
(Dynamic)
Supply Voltage(VBST)
VBST Supply Current (Static)
IBST (Static) Outputs not switching
VBST Supply Current
(Dynamic)
CLOAD=3300pF
IBST
(Dynamic)
Under Voltage Lockout
VCC-Threshold
VCC-Hysteresis
VCC_UVLO VCC Rising
VCC_Hyst VCC Falling
Rev.1.2
02/26/07
SYM
VREF
Test Condition
Min
4.5V<Vcc<5.5V
TYP
MAX
0.8
0.4
FS=300kHz
4.5
5
3
5
Units
V
%
5.5
V
mA
mA
0.15
mA
5
mA
4.2
0.22
V
V
2
NX2154/2154A
PARAMETER
SS
Soft Start time
Oscillator (Rt)
Frequency
Ramp-Amplitude Voltage
Max Duty Cycle
Min Duty Cycle
Error Amplifiers
Transconductance
Input Bias Current
Comp SD Threshold
FBUVLO
Feedback UVLO threshold
High Side Driver(C L=2200pF)
Output Impedance , Sourcing
Output Impedance , Sinking
Sourcing Current
Sinking Current
Rise Time
Fall Time
Deadband Time
SYM
Tss
Test Condition
Min
Fsw=300Khz
FS
VRAMP
TYP
MAX
3.4
1.7
mS
300
1.6
84
kHz
V
%
%
0
2000
10
0.3
Ib
percent of nominal
65
Units
70
umho
nA
V
75
%
Rsource(Hdrv)
I=200mA
Rsink(Hdrv)
I=200mA
Isource(Hdrv)
Isink(Hdrv)
THdrv(Rise)
THdrv(Fall)
Tdead(L to Ldrv going Low to Hdrv
H)
going High, 10%-10%
1.9
1.7
1
1.2
14
17
30
ohm
ohm
A
A
ns
ns
ns
Rsource(Ldrv)
I=200mA
1.9
ohm
Rsink(Ldrv)
I=200mA
1
ohm
Isource(Ldrv)
1
A
Isink(Ldrv)
2
A
13
12
10
ns
ns
ns
360
540
mV
Low Side Driver (C L=2200pF)
Output Impedance, Sourcing
Current
Output Impedance, Sinking
Current
Sourcing Current
Sinking Current
Rise Time
Fall Time
Deadband Time
OCP
OCP voltage
Rev.1.2
02/26/07
TLdrv(Rise)
TLdrv(Fall)
Tdead(H to SW going Low to Ldrv
L)
going High, 10% to 10%
NX2154
NX2154A
3
NX2154/2154A
PIN DESCRIPTIONS
PIN #
1
BST
PIN DESCRIPTION
This pin supplies voltage to the high side driver. A high frequency
ceramic capacitor of 0.1 to 1 uF must be connected from this pin to SW pin.
2
HDRV
High side MOSFET gate driver.
3
GND
Ground pin.
4
LDRV
Low side MOSFET gate driver. For the high current application, a 4.7nF capacitor is recommend to placed on low side MOSFET's gate to ground. This is to
prevent undesired Cdv/dt induced low side MOSFET's turn on to happen, which
is caused by fast voltage change on the drain of low side MOSFET in synchronous buck converter and lower the system efficiency.
5
Vcc
Voltage supply for the internal circuit as well as the low side MOSFET gate
driver. A 1uF high frequency ceramic capacitor must be connected from this pin
to GND pin.
6
FB
This pin is the error amplifier inverting input. This pin is also connected to the
output UVLO comparator. When this pin falls below 0.56V, both HDRV and
LDRV outputs are in hiccup.
7
COMP
This pin is the output of the error amplifier and together with FB pin is used to
compensate the voltage control feedback loop. This pin is also used as a shut
down pin. When this pin is pulled below 0.3V, both drivers are turned off and
internal soft start is reset.
8
SW
This pin is connected to the source of the high side MOSFET and provides
return path for the high side driver. Also SW senses the low side MOSFETS
current, when the pin voltage is lower than 360mV for NX2154, 540mV for NX2154A,
hiccup will be triggered.
Rev.1.2
02/26/07
PIN SYMBOL
4
NX2154/2154A
BLOCK DIAGRAM
VCC
70%Vp
Hiccup Logic
FB
Bias
Generator
1.25V
OC
0.8V
UVLO
BST
POR
START
HDRV
COMP
SW
0.3V
OC
Control
Logic
START 0.8V
VCC
PWM
OSC
Digital
start Up
ramp
S
R
LDRV
Q
FB
0.6V
CLAMP
COMP
START
360mV/540mV
1.3V
CLAMP
Hiccup Logic
OCP
comparator
GND
Figure 2 - Simplified block diagram of the NX2154/NX2154A
Rev.1.2
02/26/07
5
NX2154/2154A
APPLICATION INFORMATION
Symbol Used In Application Information:
VIN
- Input voltage
VOUT
- Output voltage
IOUT
- Output current
=
VIN -VOUT VOUT
1
×
×
L OUT
VIN
FS
...(2)
33V-5V 5V
1
×
×
= 0.94A
15uH 33V 300kHz
Output Capacitor Selection
DVRIPPLE - Output voltage ripple
FS
∆IRIPPLE =
Output capacitor is basically decided by the
- Working frequency
amount of the output voltage ripple allowed during steady
DIRIPPLE - Inductor current ripple
state(DC) load condition as well as specification for the
load transient. The optimum design may require a couple
Design Example
schematic is figure 1.
of iterations to satisfy both condition.
Based on DC Load Condition
The amount of voltage ripple during the DC load
VIN = 33V
condition is determined by equation(3).
The following is typical application for NX2154, the
VOUT=5V
∆IRIPPLE
8 × FS × COUT ...(3)
FS=300kHz
∆VRIPPLE = ESR × ∆IRIPPLE +
IOUT=3A
Where ESR is the output capacitors' equivalent
DVRIPPLE <=50mV
series resistance,COUT is the value of output capacitors.
DVDROOP<=250mV @ 9A step
Typically when large value capacitors are selected
such as Aluminum Electrolytic,POSCAP and OSCON
Output Inductor Selection
The selection of inductor value is based on inductor ripple current, power rating, working frequency and
efficiency. Larger inductor value normally means smaller
ripple current. However if the inductance is chosen too
large, it brings slow response and lower efficiency. Usually the ripple current ranges from 20% to 40% of the
output current. This is a design freedom which can be
types are used, the amount of the output voltage ripple
is dominated by the first term in equation(3) and the
second term can be neglected.
For this example,electrolytic capacitors are chosen as output capacitors, the ESR and inductor current
typically determines the output voltage ripple.
ESR desire =
decided by design engineer according to various application requirements. The inductor value can be calcu-
VIN -VOUT VOUT
1
×
×
∆IRIPPLE
VIN
FS
IRIPPLE =k × IOUTPUT
6ME1000WG (1000uF,30mΩ) is chosen.
...(1)
33V-5V 5V
1
×
×
0.3 × 3A 33V 300kHz
L OUT =15.7uH
L OUT =
Choose inductor from COILCRAFT DO5022P-153
with L=15uH is a good choice.
Rev.1.2
02/26/07
If low ESR is required, for most applications, multor. For example, SANYO electrolytic capacitor
where k is between 0.2 to 0.4.
Select k=0.3, then
Current Ripple is recalculated as
...(4)
tiple capacitors in parallel are better than a big capaci-
lated by using the following equations:
L OUT =
∆VRIPPLE 50mV
=
= 53m Ω
∆IRIPPLE
0.94A
N =
E S R E × ∆ IR I P P L E
∆ VR IPPLE
...(5)
Number of Capacitor is calculated as
N=
30mΩ× 0.94A
50mV
N =0.566
The number of capacitor has to be round up to a
integer. Choose N =1.
If ceramic capacitors are chosen as output ca
6
NX2154/2154A
pacitors, both terms in equation (3) need to be evalu-
of output capacitor. For low frequency capacitor such
ated to determine the overall ripple. Usually when this
as electrolytic capacitor, the product of ESR and ca-
type of capacitors are selected, the amount of capaci-
pacitance is high and L ≤ L crit is true. In that case, the
tance per single unit is not sufficient to meet the tran-
transient spec is dependent on the ESR of capacitor.
sient specification, which results in parallel configuration of multiple capacitors .
capacitors in parallel. The number of capacitors can be
For example, one 100uF, X5R ceramic capacitor
with 2mΩ ESR is used. The amount of output ripple is
∆VRIPPLE
In most cases, the output capacitors are multiple
calculated by the following
N=
0.94A
= 2mΩ× 0.94A +
8 × 300kHz × 100uF
= 5.4mV
is specified as:
∆VDROOP <∆VTRAN @ step load DISTEP
During the transient, the voltage droop during the
transient is composed of two sections. One Section is
dependent on the ESR of capacitor, the other section is
a function of the inductor, output capacitance as well as
input, output voltage. For example, for the overshoot,
when load from high load to light load with a DISTEP
transient load, if assuming the bandwidth of system is
high enough, the overshoot can be estimated as the following equation.
VOUT
× τ2
2 × L × COUT
...(6)
where τ is the a function of capacitor, etc.
0 if L ≤ L crit

τ =  L × ∆Istep
− ESR × COUT
 V
 OUT
if
L ≥ L crit
ESR × COUT × VOUT ESR E × C E × VOUT
=
∆Istep
∆Istep
VOUT
× τ2
2 × L × C E × ∆Vtran
0 if L ≤ L crit

τ =  L × ∆Istep
− ESR E × CE
 V
 OUT
...(9)
...(7)
if
L ≥ L crit
...(10)
For example, assume voltage droop during transient is 250mV for 3A load step.
If the SANYO electrolytic capaictor 6ME1000WG
(1000uF, 30mΩ ) is used, the critical inductance is given
as
L crit =
ESR E × C E × VOUT
=
∆ I step
30m Ω × 1000µF × 5V
= 50µH
3A
The selected inductor is 15uH which is smaller than
critical inductance. In that case, the output voltage transient only dependent on the ESR.
number of capacitors is
N=
where
L crit =
∆Vtran
+
where
Although this meets DC ripple spec, however it
needs to be studied for transient requirement.
Based On Transient Requirement
Typically, the output voltage droop during transient
∆Vovershoot = ESR × ∆Istep +
ESR E × ∆Istep
ESR E × ∆Istep
∆Vtran
+
VOUT
× τ2
2 × L × CE × ∆Vtran
30mΩ × 3A
+
250mV
5V
× (0) 2
2 ×15µH ×1000µF × 250mV
= 0.36
=
...(8)
where ESRE and CE represents ESR and capaci-
The number of capacitors has to satisfied both ripple
and transient requirement. Overall, we can choose N=1.
tance of each capacitor if multiple capacitors are used
in parallel.
The above equation shows that if the selected output inductor is smaller than the critical inductance, the
voltage droop or overshoot is only dependent on the ESR
Rev.1.2
02/26/07
7
NX2154/2154A
It should be considered that the proposed equation is based on ideal case, in reality, the droop or overshoot is typically more than the calculation. The equation gives a good start. For more margin, more capacitors have to be chosen after the test. Typically, for high
frequency capacitor such as high quality POSCAP especially ceramic capacitor, 20% to 100% (for ceramic)
more capacitors have to be chosen since the ESR of
capacitors is so low that the PCB parasitic can affect
FZ1 =
1
2 × π × R 4 × C2
...(11)
FZ2 =
1
2 × π × (R 2 + R3 ) × C3
...(12)
FP1 =
1
2 × π × R3 × C3
...(13)
FP2 =
the results tremendously. More capacitors have to be
1
...(14)
C × C2
2 × π × R4 × 1
C1 + C2
selected to compensate these parasitic parameters.
where FZ1,FZ2,FP1 and FP2 are poles and zeros in
Compensator Design
Due to the double pole generated by LC filter of the
the compensator. Their locations are shown in figure 4.
The transfer function of type III compensator for
power stage, the power system has 180o phase shift ,
transconductance amplifier is given by:
and therefore, is unstable by itself. In order to achieve
Ve
1 − gm × Z f
=
VOUT
1 + gm × Zin + Z in / R1
accurate output voltage and fast transient
response,compensator is employed to provide highest
possible bandwidth and enough phase margin.Ideally,the
Bode plot of the closed loop system has crossover fre-
For the voltage amplifier, the transfer function of
compensator is
phase margin greater than 50o and the gain crossing
Ve
−Z f
=
VOUT
Zin
0dB with -20dB/decade. Power stage output capacitors
To achieve the same effect as voltage amplifier,
usually decide the compensator type. If electrolytic
the compensator of transconductance amplifier must
capacitors are chosen as output capacitors, type II com-
satisfy this condition: R 4>>2/gm. And it would be desir-
pensator can be used to compensate the system, be-
able if R 1||R2||R3>>1/gm can be met at the same time.
quency between1/10 and 1/5 of the switching frequency,
cause the zero caused by output capacitor ESR is lower
than crossover frequency. Otherwise type III compensator should be chosen.
A. Type III compensator design
Zin
R3
R2
For low ESR output capacitors, typically such as
Sanyo oscap and poscap, the frequency of ESR zero
C3
sate the system with type III compensator. The following figures and equations show how to realize the type III
C2
R4
Fb
caused by output capacitors is higher than the crossover frequency. In this case, it is necessary to compen-
Zf
C1
Vout
gm
Ve
R1
Vref
compensator by transconductance amplifier.
Figure 3 - Type III compensator using
transconductance amplifier
Rev.1.2
02/26/07
8
NX2154/2154A
Case 1:
2. Set R2 equal to 10kΩ.
FLC<FESR<FO
Gain(db)
R1=
R2 × VREF 10kΩ× 0.8V
=
= 1.91kΩ
VOUT -VREF
5V-0.8V
Choose R1=1.91kΩ.
3. Set zero FZ2 = FLC and Fp1 =FESR .
4. Calculate C3 .
power stage
FLC
40dB/decade
C3 =
FESR
1
1 1
×(
)
2 × π × R2
Fz2 Fp1
1
1
1
×(
)
2 × π × 10kΩ 1.3kHz 5.3kHz
=9.2nF
=
loop gain
20dB/decade
Choose C3=10nF.
5. Calculate R3 .
R3 =
compensator
1
2 × π × FP1 × C 3
1
2 × π × 5.3kHz × 10nF
= 3kΩ
=
FZ1 FZ2 FP1 FO
FP2
Choose R3 =3kΩ.
6. Calculate R4 with FO=30kHz.
R4 =
Figure 4 - Bode plot of Type III compensator
(FLC<FESR<FO)
If electrolytic capacitors are used as output
capacitors, typical design example of type III
compensator in which the crossover frequency is
selected as FLC<FESR<FO and F O<=1/10~1/5Fs is shown
as the following steps. Here one SANYO 6ME1000WG
with 30 mΩ is chosen as output capacitor.
1. Calculate the location of LC double pole F LC
and ESR zero FESR.
FLC =
=
1
2 × π × L OUT × COUT
1
2 × π × 15uH × 1000uF
= 1.3kHz
FESR =
1
2 × π × ESR × COUT
1
2 × π × 30mΩ × 1000uF
= 5.3kHz
=
Rev.1.2
02/26/07
VOSC 2 × π × FO × L R2 × R3
×
×
Vin
ESR
R2 + R3
1.5V 2 × π × 30kHz × 15uH 10kΩ × 3kΩ
×
×
33V
30mΩ
10kΩ + 3kΩ
=9.9kΩ
=
Choose R4=10kΩ.
7. Calculate C2 with zero Fz1 at 75% of the LC
double pole by equation (11).
C2 =
1
2 × π × FZ1 × R 4
1
2 × π × 0.75 × 1.3kHz × 10k Ω
= 12.2nF
=
Choose C2=12nF.
8. Calculate C 1 by equation (14) with pole F p2 at
half the switching frequency.
C1 =
1
2 × π × R 4 × FP2
1
2 × π × 10k Ω × 150kHz
= 106pF
=
Choose C1=100pF.
9
NX2154/2154A
Case 2:
FLC<FO<FESR
R 2 × VREF
10k Ω × 0.8V
=
= 8k Ω
VOUT -VREF
1.8V-0.8V
R1 =
Gain(db)
Choose R1=8kΩ.
power stage
3. Set zero FZ2 = FLC and Fp1 =FESR .
FLC
4. Calculate R4 and C3 with the crossover
40dB/decade
frequency at 1/10~ 1/5 of the switching frequency. Set
FO=30kHz.
C3 =
loop gain
FESR
20dB/decade
compensator
1
1 1
×(
)
2 × π × R2
Fz2 Fp1
1
1
1
×(
)
2 × π × 10kΩ 6.2kHz 60.3kHz
=2.3nF
=
VOSC 2 × π × FO × L
×
× Cout
Vin
C3
R4 =
1.5V 2 × π × 30kHz × 1.5uH
×
× 440uF
5V
2.2nF
=16.9kΩ
=
FZ1 FZ2
FO FP1
FP2
Choose C3=2.2nF, R 4=16.9kΩ.
5. Calculate C2 with zero Fz1 at 75% of the LC
double pole by equation (11).
Figure 5 - Bode plot of Type III compensator
1
2 × π × FZ1 × R 4
C2 =
Design example for type III compensator are in
order. The crossover frequency has to be selected as
FLC<FO<FESR and FO<=1/10~1/5Fs. In this case, input
voltage is 5V, output voltage is 1.8V, inductor is 1.5uH,
two POSCAP 2R5TPE220MC(220uF,12 mΩ) are chosen
as output capacitor.
1.Calculate the location of LC double pole F LC
and ESR zero FESR.
FLC =
=
1
2 × π × L OUT × COUT
1
2 × π × 1.5uH × 440uF
= 6.2kHz
FESR
1
=
2 × π × ESR × C OUT
1
=
2 × π × 6m Ω × 440uF
= 60.3kHz
2. Set R2 equal to 10kΩ.
Rev.1.2
02/26/07
1
2 × π × 0.75 × 6.2kHz × 16.9kΩ
= 2nF
=
Choose C2=2.2nF.
6. Calculate C 1 by equation (14) with pole F p2 at
half the switching frequency.
1
2 × π × R 4 × FP2
C1 =
1
2 × π × 16.9kΩ × 150kHz
= 63pF
=
Choose C1=68pF.
7. Calculate R 3 by equation (13).
R3 =
1
2 × π × FP1 × C3
1
2 × π × 60.3kHz × 2.2nF
= 1.2kΩ
=
Choose R3=1.2kΩ.
10
NX2154/2154A
B. Type II compensator design
If the electrolytic capacitors are chosen as power
Vout
stage output capacitors, usually the Type II compensator can be used to compensate the system.
R2
Fb
Type II compensator can be realized by simple RC
circuit without feedback as shown in figure 6. R3 and C1
introduce a zero to cancel the double pole effect. C2
Ve
gm
R1
R3
Vref
C2
introduces a pole to suppress the switching noise. The
following equations show the compensator pole zero lo-
C1
cation and constant gain.
Gain=gm ×
R1
× R3
R1+R2
... (15)
Figure 7 - Type II compensator with
1
Fz =
2 × π × R3 × C1
Fp ≈
transconductance amplifier
... (16)
1
2 × π × R3 × C2
... (17)
For this type of compensator, FO has to satisfy
FLC<FESR<<FO<=1/10~1/5Fs.
The following is parameters for type II compensator design. Input voltage is 40V, output voltage is 5V,
output inductor is 6uH, output capacitor is one 1000uF
Gain(db)
power stage
with 30mΩ electrolytic capacitors.
40dB/decade
1.Calculate the location of LC double pole F LC
and ESR zero FESR.
FLC =
loop gain
=
20dB/decade
compensator
Gain
1
2 × π × L OUT × COUT
1
2 × π × 15uH × 1000uF
= 1.3kHz
FESR =
1
2 × π × ESR × COUT
1
2 × π × 30mΩ × 1000uF
= 5.3kHz
=
FZ FLC FESR
FO FP
2.Set R2 equal to 1kΩ.
Figure 6 - Bode plot of Type II compensator
R1 =
R 2 × VREF
1kΩ × 0.8V
=
= 191Ω
VOUT -VREF
5V-0.8V
Choose R1=191Ω.
3. Set crossover frequency at 1/10~ 1/5 of the
swithing frequency, here FO=30kHz.
4.Calculate R3 value by the following equation.
Rev.1.2
02/26/07
11
NX2154/2154A
4.Calculate R3 value by the following equation.
V
2 × π × FO × L 1 VOUT
×
×
R3 = OSC ×
Vin
RESR
gm VREF
1.5V 2 × π × 30kHz × 15uH
1
×
×
33V
30mΩ
2.0mA/V
5V
×
0.8V
=13.3kΩ
Vout
R2
Fb
=
R1
Vref
Voltage divider
Choose R 3 =13.3kΩ.
5. Calculate C1 by setting compensator zero FZ
Figure 8 - Voltage divider
at 75% of the LC double pole.
C1=
Input Capacitor Selection
1
2 × π × R 3 × Fz
Input capacitors are usually a mix of high frequency
1
2 × π × 13.3kΩ × 0.75 × 1.3kHz
=12.2nF
=
pacitors bypass the high frequency noise, and bulk capacitors supply switching current to the MOSFETs. Usually 1uF ceramic capacitor is chosen to decouple the
Choose C1=12nF.
6. Calculate C 2 by setting compensator pole Fp
at half the swithing frequency.
C2=
ceramic capacitors and bulk capacitors. Ceramic ca-
high frequency noise.The bulk input capacitors are decided by voltage rating and RMS current rating. The RMS
current in the input capacitors can be calculated as:
1
π × R 3 × Fs
IRMS = IOUT × D × 1- D
1
π × 1 3 .3k Ω × 3 0 0 k H z
=80pF
=
Choose C1=82pF.
D=
VOUT
VIN
...(19)
VIN = 33V, VOUT=5V, IOUT=3A, using equation (19),
the result of input RMS current is 1.1A.
For higher efficiency, low ESR capacitors are rec-
Output Voltage Calculation
Output voltage is set by reference voltage and
external voltage divider. The reference voltage is fixed
at 0.8V. The divider consists of two ratioed resistors
so that the output voltage applied at the Fb pin is 0.8V
when the output voltage is at the desired value. The
following equation and picture show the relationship
between
VOUT , VREF and voltage divider..
R 2 × VR E F
R 1=
V O U T -V R E F
...(18)
where R 2 is part of the compensator, and the
value of R1 value can be set by voltage divider.
See compensator design for R1 and R2 selection.
ommended. One Sanyo electrolytic capacitor
50ME180WX 50V 180uF 46mΩ with 1.19A RMS rating
is chosen as input bulk capacitors.
Power MOSFETs Selection
The power stage requires two N-Channel power
MOSFETs. The selection of MOSFETs is based on
maximum drain source voltage, gate source voltage,
maximum current rating, MOSFET on resistance and
power dissipation. The main consideration is the power
loss contribution of MOSFETs to the overall converter
efficiency. In this design example, two STM6920 are used.
They have the following parameters: V DS=40V, I D
=7A,RDSON =45mΩ,QGATE =8.7nC.
There are two factors causing the MOSFET power
loss:conduction loss, switching loss.
Rev.1.2
02/26/07
12
NX2154/2154A
Conduction loss is simply defined as:
ISET =
PHCON =IOUT 2 × D × RDS(ON) × K
PLCON =IOUT 2 × (1 − D) × RDS(ON) × K
PTOTAL =PHCON + PLCON
...(20)
where the RDS(ON) will increases as MOSFET junc-
360mV
K × RDSON
If MOSFET R DSON=45mΩ, the worst case thermal
consideration K=1.5, then
ISET =
320mV
360mV
=
= 5.3A
K × RDSON 1.5 × 45m Ω
tion temperature increases, K is RDS(ON) temperature
dependency. As a result, RDS(ON) should be selected for
the worst case, in which K approximately equals to 1.5
at 125oC according to STM6920 datasheet. Conduction
loss should not exceed package rating or overall system thermal budget.
Switching loss is mainly caused by crossover conduction at the switching transition. The total switching
loss can be approximated.
The layout is very important when designing high
frequency switching converters. Layout will affect noise
pickup and can cause a good design to perform with
less than expected results.
There are two sets of components considered in
the layout which are power components and small signal components. Power components usually consist of
1
PSW = × VIN × IOUT × TSW × FS
...(21)
2
where IOUT is output current, TSW is the sum of TR
and TF which can be found in mosfet datasheet, and FS
is switching frequency. Switching loss PSW is frequency
dependent.
Also MOSFET gate driver loss should be considered when choosing the proper power MOSFET.
MOSFET gate driver loss is the loss generated by discharging the gate capacitor and is dissipated in driver
circuits.It is proportional to frequency and is defined as:
Pgate = (QHGATE × VHGS + QLGATE × VLGS ) × FS
Layout Considerations
...(22)
where QHGATE is the high side MOSFETs gate
charge,QLGATE is the low side MOSFETs gate charge,VHGS
input capacitors, high-side MOSFET, low-side MOSFET,
inductor and output capacitors. A noisy environment is
generated by the power components due to the switching power. Small signal components are connected to
sensitive pins or nodes. A multilayer layout which includes power plane, ground plane and signal plane is
recommended .
Layout guidelines:
1. First put all the power components in the top
layer connected by wide, copper filled areas. The input
capacitor, inductor, output capacitor and the MOSFETs
should be close to each other as possible. This helps to
reduce the EMI radiated by the power loop due to the
high switching currents through them.
is the high side gate source voltage, and VLGS is the low
2. Low ESR capacitor which can handle input RMS
side gate source voltage.
This power dissipation should not exceed maximum power dissipation of the driver device.
ripple current and a high frequency decoupling ceramic
cap which usually is 1uF need to be practically touching the drain pin of the upper MOSFET, a plane connection is a must.
Over Current Limit Protection
Over current Limit for step down converter is
achieved by sensing current through the low side
3. The output capacitors should be placed as close
as to the load as possible and plane connection is required.
MOSFET. For NX2154, the current limit is decided by
4. Drain of the low-side MOSFET and source of
the RDSON of the low side mosfet. When synchronous
the high-side MOSFET need to be connected thru a plane
FET is on, and the voltage on SW pin is below 360mV,
ans as close as possible. A snubber nedds to be placed
the over current occurs. The over current limit can be
as close to this junction as possible.
calculated by the following equation.
Rev.1.2
02/26/07
5. Source of the lower MOSFET needs to be con13
NX2154/2154A
nected to the GND plane with multiple vias. One is not
back to the resistor divider should not go through high
enough. This is very important. The same applies to the
frequency signals.
output capacitors and input capacitors.
9. All GNDs need to go directly thru via to GND
6. Hdrv and Ldrv pins should be as close to
plane.
MOSFET gate as possible. The gate traces should be
10. The feedback part of the system should be
wide and short. A place for gate drv resistors is needed
kept away from the inductor and other noise sources,
to fine tune noise if needed.
and be placed close to the IC.
7. Vcc capacitor, BST capacitor or any other by-
11. In multilayer PCB, separate power ground and
passing capacitor needs to be placed first around the IC
analog ground. These two grounds must be connected
and as close as possible. The capacitor on comp to
together on the PC board layout at a single point. The
GND or comp back to FB needs to be place as close to
goal is to localize the high current path to a separate
the pin as well as resistor divider.
loop that does not interfere with the more sensitive ana-
8. The output sense line which is sensing output
log control function.
TYPICAL APPLICATION FOR HIGH CURRENT
L2 1uH
Vin
+12V
C3
33uF
C5
1uF
Cin
2 x 16SP180M
D1 MBR0530T1
Vin
7
HI=SD
M3
C1
220pF
1
BST
Comp
C2
15nF
R4
5k
6
5
Vcc
NX2154
C6
1uF
+5V
Hdrv
Gnd
2
M1 IRF3706
L1 1uH
SW
Ldrv
Fb
C4
0.1uF
8
4
M2
2 x IRF3706
Vout
+1.8V,20A
Co
2 x (1500uF,13mohm)
C7 4.7nF
3
R2
800
R1 1k
Figure 9 - High output current application of 2154
Rev.1.2
02/26/07
14
NX2154/2154A
TYPICAL APPLICATION FOR LED
+5V
Vin
78L05
+9V to 33V
D1 MBR0530T1
1uF
10k
1N4148
1uF
7
1uF
5
1
Vcc
BST
Comp
Hdrv
2
IRF7341
68nF
10uH
SW
56pF
NX2154
1.6k
6
220uF
0.1uF
Fb
Ldrv
8
Vout
Co
1000uF,30mohm
4
Gnd
3
LUXEON III star LED
LM358
0.1ohm
POT 100k
1k
Figure 10 - NX2154 LED application
Waveforms for LED application
0.9
EFFICIENCY(%)
0.85
0.8
0.75
0.7
0.65
0.6
0.55
0
0.2
0.4
0.6
0.8
1
1.2
LED CURRENT(A)
Figure 11 - LED application efficiency
(One LUXEDN III star LED, VIN=12V)
Rev.1.2
02/26/07
Figure 12 - Startup in NX2154 LED application
15
NX2154/2154A
SOIC8 PACKAGE OUTLINE DIMENSIONS
Rev.1.2
02/26/07
16
NX2154/2154A
Rev.1.2
02/26/07
17