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NSI45020JZT1G Datasheet, PDF (5/6 Pages) ON Semiconductor – Adjustable Constant Current Regulator & LED Driver
NSI45020JZT1G
Comparison of LED Circuit using CCR vs. Resistor Biasing
ON Semiconductor CCR Design
Resistor Biased Design
Constant brightness over full Supply Voltage
(more efficient), see Figure 10
Large variations in brightness over full Automotive Supply Voltage
Little variation of power in LEDs, see Figure 11
Large variations of current (power) in LEDs
Constant current extends LED strings lifetime, see Figure 10
High Supply Voltage/ Higher Current in LED strings limits lifetime
Current decreases as voltage increases, see Figure 10
Current increases as voltage increases
Current supplied to LED string decreases as temperature
increases (self-limiting), see Figure 2
LED current decreases as temperature increases
Single resistor is used for current select
Requires costly inventory
(need for several resistor values to match LED intensity)
Fewer components, less board space required
More components, more board space required
Surface mount component
Through-hole components
30
TA = 25°C
25
Circuit Current with
CCR Device
20
15
Circuit Current
with 375 W
10
Representative Test Data
5
for Figure 8 Circuit, Current
of LEDs, FR−4 @ 300 mm2,
2 oz Copper Area
0
9
10
11 12 13 14 15
16
Vin (V)
Figure 10. Series Circuit Current
180
160 TA = 25°C
140 LED Power with
120 CCR Device
100
LED Power
80 with 375 W
60
40
20
0
9
10
11
Representative Test Data
for Figure 8 Circuit, Pd of
LEDs, FR−4 @ 300 mm2,
2 oz Copper Area
12 13 14
15 16
Vin (V)
Figure 11. LED Power
Current Regulation: Pulse Mode (Ireg(P)) vs DC
Steady-State (Ireg(SS))
There are two methods to measure current regulation:
Pulse mode (Ireg(P)) testing is applicable for factory and
incoming inspection of a CCR where test times are a
minimum. (t < 300 ms). DC Steady-State (Ireg(SS)) testing is
applicable for application verification where the CCR will
be operational for seconds, minutes, or even hours. ON
Semiconductor has correlated the difference in Ireg(P) to
Ireg(SS) for stated board material, size, copper area and
copper thickness. Ireg(P) will always be greater than Ireg(SS)
due to the die temperature rising during Ireg(SS). This heating
effect can be minimized during circuit design with the
correct selection of board material, metal trace size and
weight, for the operating current, voltage, board operating
temperature (TA) and package. (Refer to Thermal
Characteristics table).
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