NSV45060JDT4G Datasheet NSV45060JDT4G, NSI45060JDT4G | P4-P6

NSI45060JDT4G

http://onsemi.com

TYPICAL PERFORMANCE CURVES

Minimum FR−4 @ 300 mm

, 2 oz Copper Trace, Still Air

Figure 2. Steady State Current (I

reg(SS)

) vs.

Anode−Cathode Voltage (Vak)

Figure 3. Pulse Current (I

reg(P)

) vs.

Anode−Cathode Voltage (Vak)

Figure 4. Steady State Current vs. Pulse

Current Testing

Vak, ANODE−CATHODE VOLTAGE (V)

reg(P)

, PULSE CURRENT (mA)

62605854

reg(P)

, PULSE CURRENT (mA)

reg(SS)

, STEADY STATE CURRENT (mA)

56 64 66

Figure 5. Current Regulation vs. Time

Figure 6. I

reg(SS)

vs. R

adj

Vak, ANODE−CATHODE VOLTAGE (V)

96543

reg(SS)

, STEADY STATE CURRENT (mA)

710

DC Test Steady State, Still Air, R

adj

= Open

= −40°C

= 25°C

= 85°C

[ −0.179 mA/°C

typ @ Vak = 7.5 V

[ −0.106 mA/°C

typ @ Vak = 7.5 V

210

= 125°C

[ −0.113 mA/°C

typ @ Vak = 7.5 V

TIME (s)

8040200

reg

, CURRENT REGULATION (mA)

Vak @ 7.5 V

= 25°C

adj

= Open

adj

(W), Max Power 125 mW

101

reg(SS)

, STEADY STATE CURRENT (mA)

100

1000

503010 70

Vak @ 7.5 V

= 25°C

7270 74 76 78

Vak @ 7.5 V

= 25°C

adj

= Open

9.08.07.06.05.04.0

3.0

Non−Repetitive Pulse Test

= 25°C

adj

= Open

Figure 7. Power Dissipation vs. Ambient

Temperature @ T

= 1755C

, AMBIENT TEMPERATURE (°C)

8060200−20−40

600

900

1500

1800

POWER DISSIPATION (mW)

700 mm

/2 oz

700 mm

/1 oz

500 mm

/1 oz

1200

2100

300

300 mm

/1 oz

500 mm

/2 oz

2400

2700

3000

300 mm

/2 oz

120100

3300

3600

3900

4200

4500

4800

140

NSI45060JDT4G

http://onsemi.com

APPLICATIONS INFORMATION

The CCR is a self biased transistor designed to regulate the

current through itself and any devices in series with it. The

device has a slight negative temperature coefficient, as

shown in Figure 2 – Tri Temp. (i.e. if the temperature

increases the current will decrease). This negative

temperature coefficient will protect the LEDS by reducing

the current as temperature rises.

The CCR turns on immediately and is typically at 20% of

regulation with only 0.5 V across it.

The device is capable of handling voltage for short

durations of up to 45 V so long as the die temperature does

not exceed 175°C. The determination will depend on the

thermal pad it is mounted on, the ambient temperature, the

pulse duration, pulse shape and repetition.

Single LED String

The CCR can be placed in series with LEDs as a High Side

or a Low Side Driver. The number of the LEDs can vary

from one to an unlimited number. The designer needs to

calculate the maximum voltage across the CCR by taking the

maximum input voltage less the voltage across the LED

string (Figures 8 and 9).

Figure 8.

Figure 9.

Higher Current LED Strings

Two or more fixed current CCRs can be connected in

parallel. The current through them is additive (Figure 10).

Figure 10.

NSI45060JDT4G

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Other Currents

The adjustable CCR can be placed in parallel with any

other CCR to obtain a desired current. The adjustable CCR

provides the ability to adjust the current as LED efficiency

increases to obtain the same light output (Figure 11).

Figure 11.

Dimming using PWM

The dimming of an LED string can be easily achieved by

placing a BJT in series with the CCR (Figure 12).

Figure 12.

The method of pulsing the current through the LEDs is

known as Pulse Width Modulation (PWM) and has become

the preferred method of changing the light level. LEDs being

a silicon device, turn on and off rapidly in response to the

current through them being turned on and off. The switching

time is in the order of 100 nanoseconds, this equates to a

maximum frequency of 10 Mhz, and applications will

typically operate from a 100 Hz to 100 kHz. Below 100 Hz

the human eye will detect a flicker from the light emitted

from the LEDs. Between 500 Hz and 20 kHz the circuit may

generate audible sound. Dimming is achieved by turning the

LEDs on and off for a portion of a single cycle. This on/off

cycle is called the Duty cycle (D) and is expressed by the

amount of time the LEDs are on (Ton) divided by the total

time of an on/off cycle (Ts) (Figure 13).

Figure 13.

The current through the LEDs is constant during the period

they are turned on resulting in the light being consistent with

no shift in chromaticity (color). The brightness is in proportion

to the percentage of time that the LEDs are turned on.

Figure 14 is a typical response of Luminance vs Duty Cycle.

Figure 14. Luminous Emmitance vs. Duty Cycle

DUTY CYCLE (%)

100908070605040

1000

3000

ILLUMINANCE (lx)

2000

4000

6000

20100

5000

Lux

Linear

Reducing EMI

Designers creating circuits switching medium to high

currents need to be concerned about Electromagnetic

Interference (EMI). The LEDs and the CCR switch

extremely fast, less than 100 nanoseconds. To help eliminate

EMI, a capacitor can be added to the circuit across R2.

(Figure 12) This will cause the slope on the rising and falling

edge on the current through the circuit to be extended. The

slope of the CCR on/off current can be controlled by the

values of R1 and C1.

The selected delay / slope will impact the frequency that

is selected to operate the dimming circuit. The longer the

delay, the lower the frequency will be. The delay time should

not be less than a 10:1 ratio of the minimum on time. The

frequency is also impacted by the resolution and dimming

steps that are required. With a delay of 1.5 microseconds on

the rise and the fall edges, the minimum on time would be

30 microseconds. If the design called for a resolution of 100

dimming steps, then a total duty cycle time (Ts) of 3

milliseconds or a frequency of 333 Hz will be required.

P1-P3 P4-P6 P7-P8

NSV45060JDT4G

Mfr. #:

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LED Lighting Drivers DPAK 60MA

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