buck regulator architectures 4.1 overview. buck-switching converters 2 synchronousnon-synchronous...
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![Page 1: Buck Regulator Architectures 4.1 Overview. Buck-Switching Converters 2 SynchronousNon-Synchronous (External-FET) Controllers (Internal-FET) Regulators](https://reader035.vdocuments.mx/reader035/viewer/2022062309/56649d165503460f949ebd31/html5/thumbnails/1.jpg)
Buck Regulator Architectures
4.1 Overview
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Buck-Switching Converters
2
Synchronous Non-Synchronous
(External-FET) Controllers
(Internal-FET) Regulators
LM3102 LM22676
LM3489LM2747
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Vin
S
D
L
C
+
-
Vout
IoIcId
Is IL
ΔIL, Ton = ΔIL, Toff
ΔIL, Ton = (Vin – Vout ) * Ton / L
ΔIL, Toff = -Vout * Toff / L
Vout = D*Vin
D = Ton / (Toff +Ton)
Non-Synchronous Buck Converters
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Buck Topology: Current and Voltage Waveforms
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Input current
Low side switch or diode
Output and Inductor
Switch
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Light-Load Operation: CCM and DCM
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t
(t)iL
oI high
oIlow
Inductor current reverses polarity at light loads
t
(t)iL
oI high
oIlow
Inductor current drops to zero before the end of the cycle: “Discontinuous Conduction Mode” (DCM)
Full SynchronousMode. Stays in Continuous Conduction Mode (CCM)
Diode or Diode Emulation
D = VOUT/VIN
D ≠ VOUT/VIN
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Cross Conduction with Synchronous Buck• Direct Connection between VIN and Ground
• High – Side and Low – Side must not be in ON state at the same time
• A time in which both MOSFET are Turned OFF is required: DEAD - TIME
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DEAD – TIME
• FIXED DEAD – TIME– Fixed time between Turn-OFF and Turn-ON– No flexibility in MOSFET choice
• ADAPTATIVE DEAD – TIME– High-Side turns ON only if LS is OFF and vice versa– Full flexibility in MOSFET choice
• It is necessary to detect the Turn-OFF of both MOSFET
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Control Mode
• Voltage Mode Control (VMC)
• Current Mode Control (CMC)– Peak Current Mode Control (PCMC)– Valley Current Mode Control (VCMC)– Average Current Mode Control (ACMC)
• Hysteretic Mode Control (HMC)
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Voltage Mode ControlAdvantages and Disadvantages• Advantages
– Stable modulation/less sensitive to noise– Single feedback path– Can work over a wide range of duty cycles
• Disadvantages– Loop gain proportional to VIN
– LC double pole often drives Type III compensation– CCM and DCM differences - a compensation challenge– Slow response to input voltage changes– Current limiting must be done separately
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Current Mode ControlAdvantages and Disadvantages• Advantages
– Power plant gain offers a single-pole roll-off– Line rejection– Cycle-by-cycle current limiting protection– Current sharing
• Disadvantages– Noise– Minimum ON-time– Sense resistor
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Hysteretic Mode ControlAdvantages and Disadvantages• Advantages
– Ultra fast transient response (preferred to use in power hungry load)– No phase compensation required; In other words, Hysteretic Mode is a kind
of large signal control
• Disadvantages– Noise Jitter susceptible– Very layout sensitive– Large switching frequency variation; Minimum ripple requirement
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Thank you!