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您現(xiàn)在的位置：買賣IC網(wǎng) > PDF目錄374018 > ADP1147AN-5 (ANALOG DEVICES INC) RADIATION HARDENED HIGH EFFICIENCY, 5 AMP SWITCHING REGULATORS PDF資料下載

參數(shù)資料

型號(hào)：	ADP1147AN-5
廠商：	ANALOG DEVICES INC
元件分類：	穩(wěn)壓器
英文描述：	RADIATION HARDENED HIGH EFFICIENCY, 5 AMP SWITCHING REGULATORS
中文描述：	SWITCHING CONTROLLER, 250 kHz SWITCHING FREQ-MAX, PDIP8
封裝：	PLASTIC, DIP-8
文件頁(yè)數(shù)：	10/12頁(yè)
文件大?。?/td>	195K
代理商：	ADP1147AN-5

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ADP1147-3.3/ADP1147-5

–10–

REV. 0

Losses are encountered in all elements of the circuit, but the

four major sources for the circuit shown in Figure 1 are:

1. T he ADP1147 dc bias current.

2. T he MOSFET gate charge current.

3. T he I

R losses.

4. T he voltage drop of the Schottky diode.

1. T he ADP1147’s dc bias current is the amount of current that

flows into V

of the device minus the gate charge current.

With V

= 10 volts, the dc supply current to the device is

typically 160

A for a no load condition, and increases pro-

portionally with load to a constant of 1.6 mA in the continu-

ous mode of operation. Losses due to dc bias currents increase

as the input voltage V

is increased. At V

= 10 volts the dc

bias losses are usually less than 1% with a load current

greater than 30 mA. When very low load currents are

encountered the dc bias current becomes the primary point

of loss.

2. T he MOSFET gate charge current is due to the switching of

the power MOSFET ’s gate capacitance. As the MOSFET ’s

gate is switched from a low to a high and back to a low again,

charge impulses dQ travel from V

to ground. T he current

out of V

is equal to dQ/dt and is usually much greater than

the dc supply current. When the device is operating in the

continuous mode the I gate charge is = f (Q

). T ypically a

P-channel power MOSFET with an R

on of 135 m

will

have a gate charge of 40 nC. With a 100 kHz, switching

frequency in the continuous mode, the I gate charge would

equate to 4 mA or about a 2%–3% loss with a V

of 10 volts.

It should be noted that gate charge losses increase with

switching frequency or input voltage. A design requiring the

highest efficiency can be obtained by using more moderate

switching frequencies.

3. I

R loss is a result of the combined dc circuit resistance

and the output load current. T he primary contributors to

circuit dc resistance are the MOSFET , the Inductor and

SENSE

. In the continuous mode of operation the average

output current is switched between the MOSFET and the

Schottky diode and a continuous current flows through the

inductor and R

SENSE

. T herefore the R

DS(ON)

of the MOSFET

is multiplied by the on portion of the duty cycle. T he result is

then combined with the resistance of the Inductor and

SENSE

. T he following equations and example show how to

approximate the I

R losses of a circuit.

DS(ON)

(

Duty Cycle

)

+ R

INDUCTOR

+ R

SENSE

= R

LOAD

R = P

LOSS

OUT

LOAD

= P

OUT

LOSS

OUT

100

= % I

LOSS

With the duty cycle = 0.5,

INDUCTOR

= 0.15,

SENSE

= 0.05

and

LOAD

= 0.5 A. T he result would be a 3% I

R loss. T he

effects of I

R losses causes the efficiency to fall off at higher

output currents.

4. At high current loads the Schottky diode can be a substantial

point of power loss. T he diode efficiency is further reduced

by the use of high input voltages. T o calculate the diode loss,

the load current should be multiplied by the duty cycle of the

diode times the forward voltage drop of the diode.

LOAD

duty cycle

DROP

Diode Loss

Figure 6 indicates the distribution of losses versus load cur-

rent in a typical ADP1147 switching regulator circuit. With

medium current loads the gate charge current is responsible

for a substantial amount of efficiency loss. At lower loads the

gate charge losses become large in comparison to the load,

and result in unacceptable efficiency levels. When low load

currents are encountered the ADP1147 employs a power

savings mode to reduce the effects of the gate loss. In the

power savings mode of operation the dc supply current is the

major source of loss and becomes a greater percentage as the

output current decreases.

L osses at higher loads are primarily due to I

R and the

Schottky diode. All other variables such as capacitor ESR

dissipation, MOSFET switching, and inductor core losses

typically contribute less than 2% additional loss.

Circuit Design E xample

In using the design example below assumptions are as follows:

= 5 Volts

OUT

= 3.3 Volts

DIODE

drop (V

) = 0.4 Volts

MAX OUT

= 1 Amp

Max switching frequency (f) = 100 kHz.

T he values for R

SENSE

, C

and L can be calculated based on the

above assumptions.

SENSE

= 100 mV/1 Amp = 100 m

OFF

time = (1/100 kHz)

[1 – (3.7/5.4)] = 3.15

= 3.15

s /(1.3

) = 242 pF.

L = 5.1

0.1

242 pF

3.3 V = 41

If we further assume:

1. T he data is specified at +25

2. MOSFET max power dissipation (P

) is limited to 250 mW.

3. MOSFET thermal resistance is 50

C/W.

4. T he normalized R

DS(ON)

vs. temperature approximation (

)

is 0.007/

T his results in 250 mW

C per watt = 12.5

C of MOSFET

heat rise. If the ambient temperature T

is 50

C, a junction

temperature of 12.5

C +50

C, T

= 62.5

P = 0.007

(62.5

C –25

C) = 0.2625

We can now determine the required R

DS(ON)

for the MOSFET :

(

)

= 5(0.25)/3.3 (1)

(1.2625) = 300

T he above requirements can be met with the use of a P-channel

IRF7204 or an Si9430.

When V

OUT

is short circuited the power dissipation of the

Schottky diode is at worst case and the dissipation can rise

greatly. T he following equation can be used to determine the

power dissipation:

SC(AVG)

DIODE

Drop

A 100 m

SENSE

resistor will yield an I

SC(AVG)

of 1 A. With a

forward diode drop of 0.4 volts a 400 milliwatt diode power

dissipation results.

T he rms current rating needed for C

will be at least 0.5 A over

the temperature range.

相關(guān)PDF資料	PDF描述
ADP1147AR-33	RADIATION HARDENED HIGH EFFICIENCY, 5 AMP SWITCHING REGULATORS
ADP1147AR-5	RADIATION HARDENED HIGH EFFICIENCY, 5 AMP SWITCHING REGULATORS
ADP1148AN-33	RADIATION HARDENED HIGH EFFICIENCY, 5 AMP SWITCHING REGULATORS
ADP1148AN-5	RADIATION HARDENED HIGH EFFICIENCY, 5 AMP SWITCHING REGULATORS
ADP1148AN	RADIATION HARDENED HIGH EFFICIENCY, 5 AMP SWITCHING REGULATORS

相關(guān)代理商/技術(shù)參數(shù)	參數(shù)描述
ADP1147AR-3.3	制造商:Rochester Electronics LLC 功能描述:HI EFF STEP-DWN SWTCH REG CONTRLR - 3.3V - Bulk
ADP1147AR-33	制造商:AD 制造商全稱:Analog Devices 功能描述:High Efficiency Step-Down Switching Regulator Controllers
ADP1147AR-5	制造商:Rochester Electronics LLC 功能描述:- Bulk
ADP1147AR-5-REEL7	制造商:Rochester Electronics LLC 功能描述:- Tape and Reel
ADP1148	制造商:AD 制造商全稱:Analog Devices 功能描述:High Efficiency Synchronous Step-Down Switching Regulators

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