參數(shù)資料
型號(hào): NCP5318FTR2
廠商: ON SEMICONDUCTOR
元件分類: 穩(wěn)壓器
英文描述: Two/Three/Four−Phase Buck CPU Controller
中文描述: SWITCHING CONTROLLER, 1000 kHz SWITCHING FREQ-MAX, PQFP32
封裝: LQFP-32
文件頁(yè)數(shù): 15/31頁(yè)
文件大?。?/td> 384K
代理商: NCP5318FTR2
NCP5318
http://onsemi.com
15
The NCP5318 provides a differential input (CSxN and
CSxP) that accepts inductor current information for each
phase as shown in Figure 17. The triangular inductor current
is measured across R
S
and amplified before being summed
with the channel startup offset, the internal ramp and the
output voltage. The internal ramp provides greater design
flexibility by allowing smaller external (current) ramps,
lower minimum pulse widths, higher frequency operation
and PWM duty cycles above 50% without external slope
compensation.
When the controller is enabled, GATEx output (GATE
output of any phase) transitions to a high voltage at the start
of the oscillator cycle for that phase, commanding a power
stage to switch on. Inductor current in that power stage then
ramps up until the combination of startup offset voltage, its
current sense signal, its internal ramp and the output voltage
ripple exceed the compensated feedback signal at the other
PWM comparator input. This brings GATEx low, which
commands that power stage off. While GATEx is high, the
Enhanced V
2
control circuit will respond to line and load
variations, but once GATEx is low, that phase cannot
respond until the next start of its oscillator cycle. Therefore,
the NCP5318 will take, at most, the off
time of the oscillator
to respond to disturbances. With multiple phases, the time to
respond to disturbances is significantly reduced due to the
increased likelihood of a GATEx being high, and closer
average proximity of oscillator starts, however the
magnitude of that response (for equivalent total inductance)
is equivalently reduced.
Turn on of a phase with higher inductor current will
terminate the PWM cycle earlier, providing negative
feedback. Current sharing is accomplished by referencing
the PWM comparators of all phases to the same Error
Amplifier signal (COMP pin).
Error Amplifier Output (COMP) Voltage No Load Bias
Point
As shown in Figure 17, the voltage present at each PWM
comparator’s non
inverting input is the sum of the channel
startup offset, output voltage, and the inductor current and
internal ramps corresponding to that phase. When the
average output current is zero, the Error Amplifier output at
the COMP pin will be:
VCOMP
VOUT
Channel_Startup_Offset
Int_Ramp
GCSA
Ext_Ramp
2
Int_Ramp is the fraction of the internal ramp (“Artificial
Ramp Amplitude” = 100 mV at a 50% duty cycle)
corresponding to the steady state duty cycle, Ext_Ramp is the
peak
to
peak external steady
state current ramp appearing
across CSxP to CSxN, G
CSA
is the current sense amplifier
gain (“Current Sense Amp to PWM Gain” = 3.0 V/V).
When the technique known as “l(fā)ossless inductor current
sensing” is used as in Figure 19, the magnitude of Ext_Ramp
is:
Ext_Ramp
D
(VIN
VOUT) (RCSx
CCSx
fSW)
where D is duty cycle expressed as a fraction.
For example, if V
OUT
at zero load is set to 1.480 volts and
the input voltage V
IN
is 12.0 V, the duty cycle (D) will be
1.480/12.0 or 12.3%. Int_Ramp will be 100 mV/50% x
12.3% = 25 mV. Realistic values for R
CSx
, C
CSx
and f
SW
are
2.5 k , 0.1 F and 350 kHz. Using these and the previously
mentioned formula, Ext_Ramp will be 14.8 mV.
VCOMP
1.480 V
3.0 V
0.60 V
14.8 mV
2
25 mV
V
2.127 Vdc.
Error Amplifier Output (COMP) Voltage Bias Point
Change with Load
In a closed loop configuration, the COMP pin may move
in order to maintain the output voltage constant when load
current changes. The required change at the COMP pin
depends partially on the scaling of the current feedback
signal as follows:
V
RS
GCSA
IOUT
N
where R
S
is the current sense resistance in each phase and
N is the number of phases.
Also, when load current changes, nonideal conversion
efficiency causes the change in input power to exceed the
change in output power, and the duty cycle becomes:
D
D
Efficiency
and
D
D
D
D
Efficiency
(D
Efficiency)
Efficiency
D
(1
Efficiency
Efficiency)
Peak to peak ripple current therefore also changes by
nearly (1
Efficiency) / Efficiency, thereby changing the
amplitude of the external ramp by this amount. The
complete change required at the COMP pin will therefore
be:
(Int_Ramp
GCSA
2
Ext_Ramp)
(1
Efficiency)
Efficiency
V
RS
GCSA
IOUT
N
相關(guān)PDF資料
PDF描述
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相關(guān)代理商/技術(shù)參數(shù)
參數(shù)描述
NCP5318FTR2G 功能描述:DC/DC 開關(guān)控制器 2/3/4 Phase Buck CPU RoHS:否 制造商:Texas Instruments 輸入電壓:6 V to 100 V 開關(guān)頻率: 輸出電壓:1.215 V to 80 V 輸出電流:3.5 A 輸出端數(shù)量:1 最大工作溫度:+ 125 C 安裝風(fēng)格: 封裝 / 箱體:CPAK
NCP5322A 制造商:ONSEMI 制造商全稱:ON Semiconductor 功能描述:Two−Phase Buck Controller with Integrated Gate Drivers and 5−Bit DAC
NCP5322A/D 制造商:ONSEMI 制造商全稱:ON Semiconductor 功能描述:Two-Phase Buck Controller with integrated Gate Drivers and 5-Bit DAC
NCP5322A_07 制造商:ONSEMI 制造商全稱:ON Semiconductor 功能描述:Two−Phase Buck Controller with Integrated Gate Drivers and 5−Bit DAC
NCP5322ADW 功能描述:DC/DC 開關(guān)控制器 2 Phase Buck w/Gate RoHS:否 制造商:Texas Instruments 輸入電壓:6 V to 100 V 開關(guān)頻率: 輸出電壓:1.215 V to 80 V 輸出電流:3.5 A 輸出端數(shù)量:1 最大工作溫度:+ 125 C 安裝風(fēng)格: 封裝 / 箱體:CPAK
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