MIC4720 Datasheet, PDF(15/21 Page) Micrel Semiconductor – 3mm x 3mm 2.0MHz 2A Integrated Switch Buck Regulator

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MIC4720 Datasheet, PDF (15/21 Pages) Micrel Semiconductor – 3mm x 3mm 2.0MHz 2A Integrated Switch Buck Regulator

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Micrel, Inc.

The following Bode analysis show the small signal loop

stability of the MIC4720, it utilizes type III compensation.

This is a dominant low frequency pole, followed by 2

zeros and finally the double pole of the inductor

capacitor filter, creating a final 20dB/decade roll off.

Bode analysis gives us a few important data points;

speed of response (Gain Bandwidth or GBW) and loop

stability. Loop speed or GBW determines the response

time to a load transient. Faster response times yield

smaller voltage deviations to load steps.

Instability in a control loop occurs when there is gain and

positive feedback. Phase margin is the measure of how

stable the given system is. It is measured by determining

how far the phase is from crossing zero when the gain is

equal to 1 (0dB).

MIC4720

Being that the MIC4720 is non-synchronous; the

regulator only has the ability to source current. This

means that the regulator has to rely on the load to be

able to sink current. This causes a non-linear response

at light loads. The following plot shows the effects of the

pole created by the nonlinearity of the output drive

during light load (discontinuous) conditions.

Typically for 3.3Vin and 1.8Vout at 2A;

â¢ Phase Margin=47 Degrees

â¢ GBW=156KHz

Gain will also increase with input voltage. The following

graph shows the increase in GBW for an increase in

supply voltage.

5Vin, 1.8Vout at 2A load;

â¢ Phase Margin=43.1 Degrees

â¢ GBW= 218KHz

3.3Vin, 1.8Vout Iout=50mA;

â¢ Phase Margin=90.5 Degrees

â¢ GBW= 64.4KHz

Feed Forward Capacitor

The feedback resistors are a gain reduction block in the

overall system response of the regulator. By placing a

capacitor from the output to the feedback pin, high

frequency signal can bypass the resistor divider, causing

a gain increase up to unity gain.

Gain and Phase

vs. Frequency

L=1ÂµH

-1 C = 4.7ÂµF

OUT

GAIN

-2 R1 = 10k

-3 R2 = 12.4k

-4

82pF

-5

-6

PHASE

-7

-8

-9

-10

100

10k 100k 1M

FREQUENCY (Hz)

The graph above shows the effects on the gain and

phase of the system caused by feedback resistors and a

feedforward capacitor. The maximum amount of phase

boost achievable with a feedforward capacitor is

graphed below.

May 2007

M9999-051707

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