LM2750LD-ADJ/NOPB National Semiconductor, LM2750LD-ADJ/NOPB Datasheet - Page 14

LM2750LD-ADJ/NOPB

Manufacturer Part Number

LM2750LD-ADJ/NOPB

Description

IC CONV REG SW CAP ADJ 10-LLP

Manufacturer

National Semiconductor

Type

Step-Up (Boost), Switched Capacitor (Charge Pump), Doublerr

Datasheet

1.LM2750LD-ADJNOPB.pdf (16 pages)

Specifications of LM2750LD-ADJ/NOPB

Internal Switch(s)

Yes

Synchronous Rectifier

Number Of Outputs

Voltage - Output

3.8 ~ 5.2 V

Current - Output

120mA

Frequency - Switching

1.7MHz

Voltage - Input

2.7 ~ 5.6 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

10-LLP

For Use With

LM2750LD-ADJEV - BOARD EVAL LM2750LD-ADJ

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Power - Output

Other names

LM2750LD-ADJ
LM2750LD-ADJTR

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LM2750 LED Drive Application

PWM BRIGHTNESS/DIMMING CONTROL

Brightness of the LEDs can be adjusted in an application by

driving the SD pin of the LM2750 with a PWM signal. When

the PWM signal is high, the LM2750 is ON, and current flows

through the LEDs, as described in the previous section. A

low PWM signal turns the part and the LEDs OFF. The

perceived brightness of the LEDs is proportional to ON

current of the LEDs and the duty cycle (D) of the PWM signal

(the percentage of time the LEDs are ON).

To achieve good brightness/dimming control with this circuit,

proper selection of the PWM frequency is required. The

PWM frequency (F

avoid visible flickering of the LED light. An upper bound on

this frequency is also needed to accomodate the turn-on

time of the LM2750 (T

recommended PWM frequency is similarly dependent on the

minimum duty cycle (D

equation puts bounds on the reommended PWM frequency

range:

Choosing a PWM frequency within these limits will result in

fairly linear control of the time-averaged LED current over

the full duty-cycle adjustment range. For most applications, a

PWM frequency between 100Hz and 500Hz is recom-

mended. A PWM frequency up to 1kHz may be acceptable in

some designs.

LED DRIVER POWER EFFICIENCY

Efficiency of an LED driver (E

power consumed by the LEDs (P

consumed at the input of the circuit. Input power consump-

tion of the LM2750 was explained and defined in the previ-

ous section titled: Power Efficiency and Power Dissipa-

tion. Assuming LED forward voltages and currents match

reasonably well, LED power consumption is the product of

the number of LEDs in the circuit (N), the LED forward

voltage (V

Figure 7 is an efficiency curve for a typical LM2750 LED-

drive application.

FIGURE 7. LM2750 LED Drive Efficiency. 6 LEDs, I

(Continued)

LED

= P

= N x V

LED

/ P

LED

), and the LED forward current (I

100Hz

20mA each, V

x I

= (NxV

PWM

LED

) should be set higher than 100Hz to

MIN

LED

PWM

) of the application. The following

= 0.5ms typ.). This maximum

LED

) is typically defined as the

) / {V

LED

MIN

= 4.0V

) divided by the power

÷ T

x [(2xI

20035127

LED

OUT

) + 5mA]}

LED

LED DRIVER POWER CONSUMPTION

For battery-powered LED-drive applications, it is strongly

recommended that power consumption, rather than power

efficiency, be used as the metric of choice when evaluating

power conversion performance. Power consumed (P

simply the product of input voltage (V

LM2750 input current is equal to twice the output current

Output voltage and LED voltage do not impact the amount of

current consumed by the LM2750 circuit. Thus, neither factor

affects the current draw on a battery. Since output voltage

does not impact input current, there is no power savings with

either the LM2750-5.0 or the LM2750-ADJ: both options

consume the same amount of power.

In the previous section, LED Driver Efficiency was defined

as:

The equation above can be simplified by recognizing the

following:

Simplification yields:

This is in direct contrast to the previous assertion that

showed that power consumption was completely indepen-

dent of LED voltage. As is the case here with the LM2750,

efficiency is often not a good measure of power conversion

effectiveness of LED driver topologies. This is why it is

strongly recommended that power consumption be studied

or measured when comparing the power conversion effic-

tiveness of LED drivers.

One final note: efficiency of an LED drive solution should not

be confused with an efficiency calculation for a standard

power converter (E

The equation above neglects power losses in the external

resistors that set LED currents and is a very poor metric of

LED-drive power conversion performance.

OUT

LED

2 x I

N x I

LED

), plus the supply current of the part (nominally 5mA):

= (2xI

= P

= V

OUT

LED

= V

LED

OUT

= I

LED

x I

/ P

OUT

) + 5mA

5mA (high output current applications)

/ V

= (NxV

= (V

OUT

LED

x I

LED

OUT

) / {V

) / (V

x [(2xI

) and input current

x I

)

OUT

) + 5mA]}

) is

LM2750LD-ADJ/NOPB National Semiconductor, LM2750LD-ADJ/NOPB Datasheet - Page 14

LM2750LD-ADJ/NOPB

Specifications of LM2750LD-ADJ/NOPB

Available stocks

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