LTC3251_15 Datasheet, PDF(8/16 Page) Linear Technology – 500mA High Efficiency, Low Noise, Inductorless Step-Down DC/DC Converter

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LTC3251_15 Datasheet, PDF (8/16 Pages) Linear Technology – 500mA High Efficiency, Low Noise, Inductorless Step-Down DC/DC Converter

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LTC3251/

LTC3251-1.2/LTC3251-1.5

OPERATIO (Refer to Block Diagram)

The LTC3251 family of parts use a dual phase switched

capacitor charge pump to step down VIN to a regulated

output voltage. Regulation is achieved by sensing the

output voltage through an external resistor divider and

modulating the charge pump output current based on the

error signal. A 2-phase nonoverlapping clock activates the

two charge pumps. The two charge pumps work in paral-

lel, but out of phase from each other. On the first phase of

the clock, current is transferred from VIN, through the

external flying capacitor 1, to VOUT via the switches of

Charge Pump 1. Not only is current being delivered to VOUT

on the first phase, but the flying capacitor is also being

charged. On the second phase of the clock, flying capaci-

tor 1 is connected from VOUT to ground, transferring the

charge stored during the first phase of the clock to VOUT via

the switches of Charge Pump 1. Charge Pump 2 operates

in the same manner, but with the phases of the clock

reversed. This dual phase architecture achieves extremely

low output and input noise by providing constant charge

transfer from VIN to VOUT.

Using this method of switching, only half of the output

current is delivered from VIN, thus achieving twice the

efficiency over a conventional LDO. A spread spectrum

oscillator, which utilizes random switching frequencies

between 1MHz and 1.6MHz, sets the rate of charging and

discharging of the flying capacitors. The LTC3251-1.2/

LTC3251-1.5 MODE pin can be used to disable spread

spectrum operation which causes switching to occur at

1.6MHz. The part also has two types of low current Burst

Mode operation to improve efficiency even at light loads.

In shutdown mode, all circuitry is turned off and the

LTC3251 family draws only leakage current from the VIN

supply. Furthermore, VOUT is disconnected from VIN. The

MD0 and MD1 pins are CMOS inputs with threshold

voltages of approximately 0.8V to allow regulator control

with low voltage logic levels. The MODE pin is also CMOS,

but has a threshold of about 1/2 â¢ VIN. The LTC3251 family

is in shutdown when a logic low is applied to both mode

pins. Since MD0, MD1 and MODE pins are high impedance

CMOS inputs, they should never be allowed to float.

Always drive MD0, MD1 and Mode with valid logic levels.

Short-Circuit/Thermal Protection

The LTC3251 family has built-in short-circuit current

limiting as well as overtemperature protection. During

short-circuit conditions, internal circuitry automatically

limits the output current to approximately 800mA. At

higher temperatures, or in cases where internal power

dissipation causes excessive self heating on chip (i.e.,

output short circuit), the thermal shutdown circuitry will

shut down the charge pumps when the junction tempera-

ture exceeds approximately 160Â°C. It will re-enable the

charge pumps once the junction temperature drops back

to approximately 150Â°C. The LTC3251 will cycle in and out

of thermal shutdown without latch-up or damage until the

overstress condition is removed. Long term overstress

(IOUT > 650mA and/or TJ > 125Â°C) should be avoided as it

can degrade the performance or shorten the life of the part.

Soft-Start

To prevent excessive current flow at VIN during start-up,

the LTC3251 family has built-in soft-start circuitry. Soft-

start is achieved by increasing the amount of current

available to the output charge storage capacitor linearly

over a period of approximately 500Âµs. Soft-start is en-

abled whenever the device is brought out of shutdown,

and is disabled shortly after regulation is achieved.

Spread Spectrum Operation

Switching regulators can be particularly troublesome where

electromagnetic interference (EMI) is concerned. Switch-

ing regulators operate on a cycle-by-cycle basis to transfer

power to an output. In most cases the frequency of

operation is either fixed or is a constant based on the

output load. This method of conversion creates large

components of noise at the frequency of operation (funda-

mental) and multiples of the operating frequency (har-

monics). Figure 1a shows a conventional buck switching

converter. Figures 1b and 1c are the input and output noise

spectrums for the buck converter of Figure 1 with VIN =

3.6V, VOUT = 1.5V and IOUT = 500mA.

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