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參數(shù)資料

型號：	MIC4425BM
廠商：	MICREL INC
元件分類：	功率晶體管
英文描述：	100000 SYSTEM GATE 1.8 VOLT FPGA - NOT RECOMMENDED for NEW DESIGN
中文描述：	3 A 2 CHANNEL, BUF OR INV BASED MOSFET DRIVER, PDSO8
封裝：	SOIC-8
文件頁數(shù)：	9/12頁
文件大小：	117K
代理商：	MIC4425BM

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January 1999

MIC4423/4424/4425

Micrel

in estimating power dissipation in the driver. Operating

frequency, power supply voltage, and load all affect power

dissipation.

Given the power dissipation in the device, and the thermal

resistance of the package, junction operating temperature for

any ambient is easy to calculate. For example, the thermal

resistance of the 8-pin plastic DIP package, from the datasheet,

is 150

C/W. In a 25

C ambient, then, using a maximum

junction temperature of 150

C, this package will dissipate

960mW.

Accurate power dissipation numbers can be obtained by

summing the three sources of power dissipation in the device:

Load power dissipation (P

)

Quiescent power dissipation (P

)

Transition power dissipation (P

)

Calculation of load power dissipation differs depending on

whether the load is capacitive, resistive or inductive.

Resistive Load Power Dissipation

Dissipation caused by a resistive load can be calculated as:

= I

where:

I = the current drawn by the load

= the output resistance of the driver when the

output is high, at the power supply voltage used

(See characteristic curves)

D = fraction of time the load is conducting (duty cycle)

Capacitive Load Power Dissipation

Dissipation caused by a capacitive load is simply the energy

placed in, or removed from, the load capacitance by the driver.

The energy stored in a capacitor is described by the equation:

E = 1/2 C V

As this energy is lost in the driver each time the load is charged

or discharged, for power dissipation calculations the 1/2 is

removed. This equation also shows that it is good practice not

to place more voltage in the capacitor than is necessary, as

dissipation increases as the square of the voltage applied to

the capacitor. For a driver with a capacitive load:

= f C (V

)

where:

f = Operating Frequency

C = Load Capacitance

= Driver Supply Voltage

Inductive Load Power Dissipation

For inductive loads the situation is more complicated. For the

part of the cycle in which the driver is actively forcing current

into the inductor, the situation is the same as it is in the

resistive case:

= I2 R

However, in this instance the R

required may be either the

on resistance of the driver when its output is in the high state,

or its on resistance when the driver is in the low state,

depending on how the inductor is connected, and this is still

only half the story. For the part of the cycle when the inductor

is forcing current through the driver, dissipation is best

described as

= I V

(1 – D)

where V

is the forward drop of the clamp diode in the driver

(generally around 0.7V). The two parts of the load dissipation

must be summed in to produce P

= P

+ P

Quiescent Power Dissipation

Quiescent power dissipation (P

, as described in the input

section) depends on whether the input is high or low. A low

input will result in a maximum current drain (per driver) of

≤

0.2mA; a logic high will result in a current drain of

≤

2.0mA.

Quiescent power can therefore be found from:

= V

[D I

+ (1 – D) I

]

where:

= quiescent current with input high

= quiescent current with input low

D = fraction of time input is high (duty cycle)

= power supply voltage

Transition Power Dissipation

Transition power is dissipated in the driver each time its output

changes state, because during the transition, for a very brief

interval, both the N- and P-channel MOSFETs in the output

totem-pole are ON simultaneously, and a current is conducted

through them from V

to ground. The transition power

dissipation is approximately:

= f V

(As)

where (As) is a time-current factor derived from Figure 2.

Total power (P

) then, as previously described is just

= P

+ P

Examples show the relative magnitude for each term.

EXAMPLE 1: A MIC4423 operating on a 12V supply driving

two capacitive loads of 3000pF each, operating at 250kHz,

with a duty cycle of 50%, in a maximum ambient of 60

First calculate load power loss:

= f x C x (V

)

= 250,000 x (3 x 10

–9

+ 3 x 10

–9

) x 12

= 0.2160W

Then transition power loss:

= f x V

x (As)

= 250,000 12 2.2 x 10

–9

= 6.6mW

Then quiescent power loss:

= V

x [D x I

+ (1 – D) x I

]

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