MIC2183_05 Datasheet, PDF(9/12 Page) Micrel Semiconductor – Low Voltage Synchronous Buck PWM Control IC

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MIC2183_05 Datasheet, PDF (9/12 Pages) Micrel Semiconductor – Low Voltage Synchronous Buck PWM Control IC

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MIC2183

The MIC2183 controller is broken down into 7 functions.

â¢ Control loop

â¢ PWM operation

â¢ Current mode control

â¢ Current limit

â¢ Reference, enable and UVLO

â¢ FreqOut

â¢ MOSFET gate drive

â¢ Oscillator and Sync

â¢ Soft-start

Control Loop

PWM Control Loop

The MIC2183 uses current mode control to regulate the

output voltage. This dual control loop method (illustrated in

Figure 2) senses the output voltage (outer loop) and the

inductor current (inner loop). It uses inductor current and

output voltage to determine the duty cycle of the buck

converter. Sampling the inductor current effectively removes

the inductor from the control loop, which simplifies compen-

sation.

VIN

Switching

Converter

VOUT

Switch

Driver

IINDUCTOR

Voltage

Divider

VERROR

VREF

IINDUCTOR

VERROR

tON

tPER

D = tON/tPER

Figure 2. Current Mode Control Example

As shown in Figure 1, the inductor current is sensed by

measuring the voltage across the resistor, RSENSE. A ramp is

added to the amplified current sense signal to provide slope

compensation, which is required to prevent unstable opera-

tion at duty cycles greater than 50%.

A transconductance amplifier is used for the error amplifier,

which compares an attenuated sample of the output voltage

with a reference voltage. The output of the error amplifier is

the compensation pin (Comp), which is compared to the

current sense waveform in the PWM block. When the current

signal becomes greater than the error signal, the comparator

turns off the high side drive. The COMP pin provides access

to the output of the error amplifier and allows the use of

external components to stabilize the voltage loop.

Micrel, Inc.

Current Limit

The output current is detected by the voltage drop across the

external current sense resistor (RSENSE in Figure 1.). The

current sense resistor must be sized using the minimum

current limit threshold. The external components must be

designed to withstand the maximum current limit. The current

sense resistor value is calculated by the equation below:

RSENSE

MIN

CURRENT _ SENSE

IOUT _ MAX

THRESHOLD

The maximum output current is:

IOUT _ MAX

MAX

CURRENT _ SENSE

RSENSE

THRESHOLD

The current sense pins CSH (pin 9) and CSL (pin 8) are noise

sensitive due to the low signal level and high input imped-

ance. The PCB traces should be short and routed close to

each other. A small (1nF) capacitor across the pins will

attenuate high frequency switching noise.

When the peak inductor current exceeds the current limit

threshold, the overcurrent comparator turns off the high side

MOSFET for the remainder of the switching cycle, effectively

decreasing the duty cycle. The output voltage drops as

additional load current is pulled from the converter. When the

voltage at the feedback pin (FB) reaches approximately 0.3V,

the circuit enters frequency foldback mode and the oscillator

frequency will drop to 1/4 of the switching frequency. This

limits the maximum output power delivered to the load under

a short circuit condition.

Reference, Enable and UVLO Circuits

The output drivers are enabled when the following conditions

are satisfied:

â¢ The VDD voltage (pin 10) is greater than its

undervoltage threshold.

â¢ The voltage on the enable pin (pin 7) is greater

than the enable UVLO threshold.

The enable pin (pin 7) has two threshold levels, allowing the

MIC2183 to shut down in a low current mode, or turn off output

switching in standby mode. An enable pin voltage lower than

the shutdown threshold turns off all the internal circuitry and

places the MIC2183 in a micropower shutdown mode.

If the enable pin voltage is between the shutdown and

standby thresholds, the internal bias, VDD and reference

voltages are turned on. The soft start pin is forced low by an

internal discharge MOSFET. The output drivers are inhibited

from switching. The OUTP pin is in a high state and the OUTN

pin remains in a low state. Raising the enable voltage above

the standby threshold allows the soft start capacitor to charge

and enables the output drivers. The standby threshold is

specified in the electrical characteristics. A resistor divider

can be used with the enable pin to prevent the power supply

from turning on until a specified input voltage is reached. The

circuit in Figure 3 shows how to connect the resistors.

April 2005

M9999-042205

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