ZXLD1360

A Product Line of
Diodes Incorporated
ZXLD1360
30V 1A LED DRIVER with AEC-Q100
Pin Assignments
Description
The ZXLD1360 is a continuous mode inductive step-down
converter with integrated switch and high side current sense.
VIN
LX
It operates from an input supply from 7V to 30V driving single
or multiple series connected LEDs efficiently externally
adjustable output current up to 1mA.
GND
ADJ
The ZXLD1360 has been qualified to AEC-Q100 Grade 1
enabling operation in ambient temperatures from -40°C to
125°C.
ISENSE
TSOT23-5
Top View
The output current can be adjusted by applying a DC voltage
or a PWM waveform to the ADJ pin; 100:1 adjustment of
output current is possible using PWM control. Applying
0.2V or lower to the ADJ pin turns the output off and switches
the device into a low current standby state.
Features
Typical Application Circuit
•
Simple low parts count
•
Single pin on/off and brightness control using DC voltage
or PWM
•
High efficiency (up to 95%)
•
Wide input voltage range: 7V to 30V
•
40V transient capability
•
Qualified to AEC-Q100 Grade 1
•
Available in thermally enhanced packages
o
TSOT23-5
θJA
C1
4.7µF
82° C/W
Available in Green molding (no Br, Sb) with lead free
finish/RoHS compliant
•
Up to 1MHz switching frequency
•
Typical 4% output current accuracy
Document number: DS33471 Rev. 4 - 2
RS
L1
0.1Ω
47µH
VIN
•
ZXLD1360
VIN`
7~30V
ADJ
LX
SET
ZXLD1360
GND
GND
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ZXLD1360
Block Diagram
D1
VIN
L1
RS
5 VIN
5V
C1
4.7µF
`
4 ISENSE
1 LX
R1
Voltage
regulator
0.2V
Low voltage
detector
MN
ADJ
3
R4
200k
R5
20k
R2
D1
1.25V
R3
1.35V
GND
2
Figure 1. Block diagram – With Pin Connections
Pin Descriptions
Name
Pin No.
LX
GND
1
2
Description
Drain of NDMOS switch
Ground (0V)
Multi-function On/Off and brightness control pin:
•
Leave floating for normal operation.(VADJ = VREF = 1.25V giving nominal average output current
•
•
ADJ
3
•
•
•
ISENSE
4
VIN
5
o IOUTnom = 0.1/RS)
Drive to voltage below 0.2V to turn off output current
Drive with DC voltage (0.3V < VADJ < 2.5V) to adjust output current from 25% to 200% of
IOUTnom
Drive with PWM signal from open-collector or open-drain transistor, to adjust output current.
Adjustment range 25% to 100% of IOUTnom for f>10kHz and 1% to 100% of IOUTnom for f <
500Hz
Connect a capacitor from this pin to ground to increase soft-start time.
(Default soft-start time = 500µs. Additional soft-start time is approximately 500µs/nF)
Connect resistor RS from this to VIN to define nominal average output current IOUTnom=0.1/RS
(Note: RSMIN=0.1V with ADJ pin open circuit)
Input voltage (7V to 30V). Decouple to ground with 4.7µF of higher X7R ceramic capacitor close to
device
ZXLD1360
Document number: DS33471 Rev. 4 - 2
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ZXLD1360
Absolute Maximum Ratings (Voltages to GND Unless Otherwise Stated)
Symbol
VIN
Parameter
Rating
-0.3 to +30
Input Voltage
VSENSE
VLX
ILX
PTOT
V
(40V for 0.5 sec)
+0.3 to -5
ISENSE Voltage
(measured with respect to VIN)
-0.3 to +30
LX Output Voltage
VADJ
Unit
V
(40V for 0.5 sec)
Adjust Pin Input Voltage
Switch Output Current
Power Dissipation
(Refer to Package thermal de-rating curve on page 20)
V
-0.3 to +6
V
1.25
A
1
W
TST
Storage Temperature
-55 to 150
°C
TJ MAX
Junction Temperature
150
°C
These are stress ratings only. Operation above the absolute maximum rating may cause device failure. Operation at the absolute maximum ratings, for extended
periods, may reduce device reliability.
ESD Susceptibility
Human Body Model
Machine Model
Rating
Unit
500
<100
V
V
Semiconductor devices are ESD sensitive and may be damaged by exposure to ESD events. Suitable ESD precautions should be taken when handling and
transporting these devices.
The human body model is a 100pF capacitor discharge through a 1.5kΩ resistor pin. The machine model is a 200pF capacitor discharged directly into each pin
Thermal Resistance
Symbol
Parameter
Rating
Unit
θJA
Junction to Ambient
82
°C/W
ΨJB
Junction to Board
33
°C/W
Recommended Operating Conditions
Symbol
Parameter
VIN
Input Voltage Range
ILX
Maximum recommended continuous/RMS switch current
External control voltage range on ADJ pin for DC brightness
control (Note 2)
VADJ
VADJoff
Min
Max
Units
7
30
V
1
A
2.5
V
0.3
DC voltage on ADJ pin to ensure devices is off
tONmin_REC Recommended minimum switch “ON” time
fLX max
Notes:
Recommended maximum operating frequency (Note 1)
0.25
V
800
ns
625
kHz
DLX
Duty cycle range
0.01
0.99
TA
Ambient operating temperature range
-40
125
°C
1. ZXLD1360 will operate at higher frequencies but due to propagation delays accuracy will be affected.
2.100% brightness corresponds to VADJ = VADJ(nom) = VREF (~1.25V). Driving the ADJ pin above VREF will increase the VSENSE threshold and output
current proportionally.
ZXLD1360
Document number: DS33471 Rev. 4 - 2
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ZXLD1360
Electrical Characteristics
Symbol
(Test conditions: VIN = 12V, TA = 25°C, unless otherwise specified. Note 3)
Parameter
Condition
Min.
Typ.
Max.
Unit
VSU
Internal regulator start-up threshold
VIN rising
5.65
V
VSD
Internal regulator shutdown threshold
VIN falling
5.55
V
Quiescent supply current with output off
ADJ pin grounded
20
40
µA
Quiescent supply current with output switching
ADJ pin floating
f=250kHz
1.8
5.0
mA
Mean current sense threshold voltage
(Defines LED current setting accuracy)
Measured on ISENSE pin
with respect to VIN
VADJ = 1.25V
100
105
mV
10
µA
IINQoff
IINQon
VSENSE
95
VSENSEHYS Sense threshold hysteresis
ISENSE
VREF
±15
VSENSE = VIN-0.1
1.25
Internal reference voltage
Measured on ADJ pin
with pin floating
1.25
V
50
ppm/°C
ΔVREF/ΔT Temperature coefficient of VREF
External control voltage range on ADJ pin for DC
brightness control (Note 2)
VADJ
%
ISENSE pin input current
0.3
2.5
V
VADJoff
DC voltage on ADJ pin to switch device from
active (on) state to quiescent (off) state
VADJ falling
0.15
0.2
0.25
V
VADJon
DC voltage on ADJ pin to switch device from
quiescent (off) state to active (on) state
VADJ rising
0.2
0.25
0.3
V
0 < VADJ < VREF
135
13.5
250
25
kΩ
RADJ
Resistance between ADJ pin and VREF
ILXmean
VADJ > VREF +100mV
Continuous LX switch current
RLX
LX switch ‘On’ resistance
ILX(leak)
LX switch leakage current
@ ILX=0.55A
Duty cycle range of PWM signal applied to ADJ
DPWM(LF) pin during low frequency PWM dimming mode
Brightness control range
PWM frequency <500Hz
PWM amplitude = VREF
Measured on ADJ pin
Duty cycle range of PWM signal applied to ADJ
pin during high frequency PWM dimming mode
PWM frequency >10kHz
PWM amplitude = VREF
Measured on ADJ pin
DPWM(HF)
Brightness control range
Soft start time
tSS
Operating frequency
(See graphs for more details)
fLX
0.5
0.01
1
A
1.0
Ω
5
µA
1
100:1
0.16
1
5:1
Time taken for output
current to reach 90% of
final value after voltage
on ADJ pin has risen
above 0.3V
500
µs
ADJ pin floating
L = 33µH (0.093V)
IOUT = 1A @ VLED = 3.6V
Driving 1 LED
280
kHz
tOFFMIN
Minimum switch off-time
200
ns
tONMIN
Minimum switch on-time
240
ns
Internal comparator propagation delay
50
ns
tPD
Notes:
3.
Production testing of the device is performed at 25°C. Functional operation of the device and parameters specified over a -40°C to +125°C
temperature range, are guaranteed by design, characterization and process control.
ZXLD1360
Document number: DS33471 Rev. 4 - 2
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ZXLD1360
Device Description
The device, in conjunction with the coil (L1) and current sense resistor (RS), forms a self-oscillating continuous-mode buck
converter.
Device operation (refer to Figure 1 - Block diagram and Figure 2 Operating waveforms)
Operation can be best understood by assuming that the ADJ pin of the device is unconnected and the voltage on this pin
(VADJ) appears directly at the (+) input of the comparator.
When input voltage VIN is first applied, the initial current in L1 and RS is zero and there is no output from the current sense
circuit. Under this condition, the (-) input to the comparator is at ground and its output is high. This turns MN on and switches
the LX pin low, causing current to flow from VIN to ground, via RS, L1 and the LED(s). The current rises at a rate determined
by VIN and L1 to produce a voltage ramp (VSENSE) across RS. The supply referred voltage VSENSE is forced across internal
resistor R1 by the current sense circuit and produces a proportional current in internal resistors R2 and R3. This produces a
ground referred rising voltage at the (-) input of the comparator. When this reaches the threshold voltage (VADJ), the
comparator output switches low and MN turns off. The comparator output also drives another NMOS switch, which bypasses
internal resistor R3 to provide a controlled amount of hysteresis. The hysteresis is set by R3 to be nominally 15% of VADJ.
When MN is off, the current in L1 continues to flow via D1 and the LED(s) back to VIN. The current decays at a rate
determined by the LED(s) and diode forward voltages to produce a falling voltage at the input of the comparator. When this
voltage returns to VADJ, the comparator output switches high again. This cycle of events repeats, with the comparator input
ramping between limits of VADJ ± 15%.
Switching thresholds
With VADJ = VREF, the ratios of R1, R2 and R3 define an average VSENSE switching threshold of 100mV (measured on the
ISENSE pin with respect to VIN). The average output current IOUTnom is then defined by this voltage and RS according to:
IOUTnom = 100mV/RS
Nominal ripple current is ±15mV/RS
Adjusting output current
The device contains a low pass filter between the ADJ pin and the threshold comparator and an internal current limiting
resistor (200kV nom) between ADJ and the internal reference voltage. This allows the ADJ pin to be overdriven with either
DC or pulse signals to change the VSENSE switching threshold and adjust the output current. The filter is third order,
comprising three sections, each with a cut-off frequency of nominally 4kHz.
Details of the different modes of adjusting output current are given in the applications section.
Output shutdown
The output of the low pass filter drives the shutdown circuit. When the input voltage to this circuit falls below the threshold
(0.2V nom.), the internal regulator and the output switch are turned off. The voltage reference remains powered during
shutdown to provide the bias current for the shutdown circuit. Quiescent supply current during shutdown is nominally 20mA
and switch leakage is below 5mA.
ZXLD1360
Document number: DS33471 Rev. 4 - 2
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ZXLD1360
Device Description
VIN
LX voltage
0V
Toff
Ton
VIN
115mV
85mV
SENSE voltage
100mV
VSENSEVSENSE+
IOUTnom +15%
IOUTnom
Coil current
IOUTnom -15%
0V
Comparator
input voltage
0.15VADJ
VADJ
0.15VADJ
Comparator
output
5V
0V
Figure 2. Operating Waveforms
ZXLD1360
Document number: DS33471 Rev. 4 - 2
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ZXLD1360
Device Description (cont.)
Actual operating waveforms [VIN=15V, RS=0.1V, L=33µH]
Normal operation. Output current (Ch1) and LX voltage (Ch2)
Actual operating waveforms [VIN=30V, RS=0.1V, L=33µH]
Normal operation. Output current (Ch1) and LX voltage (Ch2)
ZXLD1360
Document number: DS33471 Rev. 4 - 2
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ZXLD1360
Typical Operating Characteristics
ZXLD1360 Output C urrent
L = 33µH
1060
ZXLD1360 Output Current
L = 33µH
10%
8%
Output Current Deviation (%)
1040
Output Current (mA)
1020
1000
980
960
940
920
900
6%
4%
2%
0%
-2%
-4%
-6%
-8%
0
1 LED
5
2 LED s
15
10
20
25
Supply Voltage V IN (V)
3 LED s
4 LED s
5 LED s
30
6 LED s
-10%
35
7 LED s
8 LED s
0
1 LED
ZXLD1360 Switching Frequency
L = 33µH
5
2 LED s
3 LED s
4 LED s
5 LED s
30
6 LED s
35
7 LED s
8 LED s
ZXLD1360 Duty Cycle
L = 33µH
100
600
15
10
20
25
Supply Voltage V IN (V)
90
80
70
400
Duty Cycle (%)
Switching Frequency (kHz)
500
300
200
60
50
40
30
20
100
10
0
1 LED
0
5
2 LED s
15
10
20
25
Supply Voltage V IN (V)
3 LED s
4 LED s
ZXLD1360
Document number: DS33471 Rev. 4 - 2
5 LED s
6 LED s
30
7 LED s
0
0
35
8 LED s
1 LED
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5
2 LED s
15
10
20
25
Supply Voltage V IN (V)
3 LED s
4 LED s
5 LED s
30
6 LED s
7 LED s
35
8 LED s
March 2011
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Diodes Incorporated
ZXLD1360
Typical Operating Characteristics (Cont.)
ZXLD1360 Output Current
L = 47µH
1060
ZXLD1360 Output Current
L = 47µH
10%
8%
Output Current Deviation (%)
1040
Output Current (mA)
1020
1000
980
960
940
920
900
6%
4%
2%
0%
-2%
-4%
-6%
-8%
0
1 LED
5
2 LED s
15
10
20
25
Supply Voltage V IN (V)
3 LED s
4 LED s
5 LED s
30
6 LED s
-10%
35
7 LED s
8 LED s
0
1 LED
ZXLD1360 Switching Frequency
L = 47µH
5
2 LED s
3 LED s
4 LED s
5 LED s
30
6 LED s
35
7 LED s
8 LED s
ZXLD1360 Duty Cycle
L = 47µH
100
600
15
10
20
25
Supply Voltage V IN (V)
90
80
70
400
Duty Cycle (%)
Switching Frequency (kHz)
500
300
200
60
50
40
30
20
100
10
0
1 LED
0
5
2 LED s
15
10
20
25
Supply Voltage V IN (V)
3 LED s
4 LED s
ZXLD1360
Document number: DS33471 Rev. 4 - 2
5 LED s
6 LED s
30
7 LED s
0
0
35
8 LED s
1 LED
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5
2 LED s
15
10
20
25
Supply Voltage V IN (V)
3 LED s
4 LED s
5 LED s
30
6 LED s
7 LED s
35
8 LED s
March 2011
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Diodes Incorporated
ZXLD1360
Typical Operating Characteristics (Cont.)
ZXLD1360 Output Current
L = 100µH
1060
ZXLD1360 Output Current
L = 100µH
10%
8%
Output Current Deviation (%)
1040
Output Current (mA)
1020
1000
980
960
940
920
900
6%
4%
2%
0%
-2%
-4%
-6%
-8%
0
1 LED
5
2 LED s
15
10
20
25
Supply Voltage V IN (V)
3 LED s
4 LED s
5 LED s
30
6 LED s
-10%
35
7 LED s
8 LED s
0
1 LED
ZXLD1360 Switching Frequency
L =100µH
5
2 LED s
3 LED s
4 LED s
5 LED s
30
6 LED s
35
7 LED s
8 LED s
ZXLD1360 Duty Cycle
L = 100µH
100
600
15
10
20
25
Supply Voltage V IN (V)
90
80
70
400
Duty Cycle (%)
Switching Frequency (kHz)
500
300
200
60
50
40
30
20
100
10
0
1 LED
0
5
2 LED s
15
10
20
25
Supply Voltage V IN (V)
3 LED s
4 LED s
ZXLD1360
Document number: DS33471 Rev. 4 - 2
5 LED s
6 LED s
30
7 LED s
0
0
35
8 LED s
1 LED
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5
2 LED s
15
10
20
25
Supply Voltage V IN (V)
3 LED s
4 LED s
5 LED s
30
6 LED s
7 LED s
35
8 LED s
March 2011
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ZXLD1360
Typical Operating Characteristics (Cont.)
1.4
1.2372
1.2
1.2371
V REF (V)
1.2370
1.2369
V REF (V)
V REF (V)
1
0.8
0.6
1.2368
1.2367
0.4
1.2366
0.2
0
0
1.2365
1
2
3
4
5
6
Supply Voltage V IN (V)
VREF vs. Supply Voltage
7
1.2364
8
0
600
5
15
10
20
25
Supply Voltage V IN (V)
VREF vs. Supply Voltage
30
35
18
16
500
14
400
IIN (µA)
12
300
200
10
8
6
4
100
2
0
0
15
10
20
25
30
Supply Voltage V IN (V)
Supply Current vs. Supply Voltage
5
0
35
0
15
10
20
25
30
Supply Voltage VI N (V)
Shutdown Current vs. Supply Voltage
5
35
1200
LED Current (mA)
1200
800
600
400
200
0
0
1
2
ADJ Pin Voltage (V)
R = 100mΩ
ZXLD1360
Document number: DS33471 Rev. 4 - 2
R = 150mΩ
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R = 330mΩ
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ZXLD1360
Typical Operating Characteristics (Cont.)
ZXLD1360 Response Time vs. Temperature
LX Switch “On” Resistance vs. Temperature
Ty pical minimum LX ‘on’ and ‘off’ t ime
350
0.80
300
0.70
Response Time (ns)
250
0.60
200
0.50
150
0.40
100
0.30
50
0
-55
-35
-15
5
25 45 65 85
Ambient Temperature ( °C)
Min LX on
0.20
-50
105 125
50
100
150
Ambient Temperature ( ° C)
200
Voltage Across RSENSE (0.333Ω ) vs. Temperature
V ADJ vs. Temperature
L = 470µH, RS = 0.33Ω
1.24
0
Min LX of f
100.4
100.2
100
1.235
99.8
V SENSE (V)
V ADJ (V)
1.23
1.225
99.6
99.4
99.2
1.22
99
98.8
1.215
98.6
1.21
-55
-35
12V, Single LED
12V, Three LED
24V, Single LED
98.4
-55
105 125
24V, Three LED
-35
0.4
0.4
0.3
0.2
0.1
0
-0.1
-0.2
-0.3
-15
5
25 45 65 85
Ambient Temperature ( ° C)
12V, Single LED
Output Current Change vs. Temperature
V IN = 12V, L = 470µH, RS = 0.33Ω
Deviation from Nominal Set Value (%)
Deviation from Nominal Set Value (%)
0.5
-15
5
25 45 65 85
Ambient Temperature (°C)
12V, Three LED
105 125
24V, Single LED
24V, Three LED
Output Current Change vs. Temperature
V IN = 24V, L = 470µH, RS = 0.33Ω
0.2
0
-0.2
-0.4
-0.6
-0.8
-0.4
-0.5
-55
-35
-15
5
25 45 65 85
Ambient Temperature ( ° C)
12V, Single LED
ZXLD1360
Document number: DS33471 Rev. 4 - 2
105 125
12V, Three LED
-1
-55
-35
-15
5
25 45 65 85
Ambient Temperature (° C)
24V, Single LED
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105 125
24V, Three LED
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ZXLD1360
Application Information
Setting nominal average output current with external resistor RS
The nominal average output current in the LED(s) is determined by the value of the external current sense resistor (RS)
connected between VIN and ISENSE and is given by:
IOUTnom = 0.1/RS [for RS > 0.1Ω]
The table below gives values of nominal average output current for several preferred values of current setting resistor (RS) in
the typical application circuit shown on page 1:
RS (Ω)
Nominal average
output current (mA)
0.1
1000
0.13
760
0.15
667
The above values assume that the ADJ pin is floating and at a nominal voltage of VREF (=1.25V). Note that RS = 0.1V is the
minimum allowed value of sense resistor under these conditions to maintain switch current below the specified maximum
value.
It is possible to use different values of RS if the ADJ pin is driven from an external voltage. (See next section).
Output current adjustment by external DC control voltage
The ADJ pin can be driven by an external dc voltage (VADJ), as shown, to adjust the output current to a value above or below
the nominal average value defined by RS.
+
ADJ
ZXLD1360
G ND
DC
GND
The nominal average output current in this case is given by:
IOUTdc = (VADJ /1.25) x (100mV/RS) [for 0.3< VADJ <2.5V]
Note that 100% brightness setting corresponds to VADJ = VREF. When driving the ADJ pin above 1.25V, RS must be
increased in proportion to prevent IOUTdc exceeding 550mA maximum.
The input impedance of the ADJ pin is 50kΩ ±25% for voltages below VREF and 20kΩ ±25% for voltages above VREF
+100mV.
ZXLD1360
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ZXLD1360
Application Information (cont.)
Directly driving ADJ input
A Pulse Width Modulated (PWM) signal with duty cycle DPWM can be applied to the ADJ pin, as shown below, to adjust the
output current to a value above or below the nominal average value set by resistor RS:
PWM
VADJ
ADJ
0V
ZXLD1360
GND
GND
Driving the ADJ input via open collector transistor
The recommended method of driving the ADJ pin and controlling the amplitude of the PWM waveform is to use a small NPN
switching transistor as shown below:
ADJ
PWM
ZXLD1360
GND
GND
This scheme uses the 200k resistor between the ADJ pin and the internal voltage reference as a pull-up resistor for the
external transistor.
Driving the ADJ input from a microcontroller
Another possibility is to drive the device from the open drain output of a microcontroller. The diagram below shows one
method of doing this:
MCU
10k
ADJ
ZXLD1360
GND
If the NMOS transistor within the microcontroller has high Drain / Source capacitance, this arrangement can inject a negative
spike into ADJ input of the 1360 and cause erratic operation but the addition of a Schottky clamp diode (cathode to ADJ) to
ground and inclusion of a series resistor (10k) will prevent this. See the section on PWM dimming for more details of the
various modes of control using high frequency and low frequency PWM signals.
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Application Information (cont.)
Shutdown Mode
Taking the ADJ pin to a voltage below 0.2V for more than approximately 100µs will turn off the output and supply current to a
low standby level of 20µA nominal.
Note that the ADJ pin is not a logic input. Taking the ADJ pin to a voltage above VREF will increase output current above the
100% nominal average value. (See graphs for details).
Soft-start
The device has inbuilt soft-start action due to the delay through the PWM filter. An external capacitor from the ADJ pin to
ground will provide additional soft-start delay, by increasing the time taken for the voltage on this pin to rise to the turn-on
threshold and by slowing down the rate of rise of the control voltage at the input of the comparator. With no external
capacitor, the time taken for the output to reach 90% of its final value is approximately 500μs. Adding capacitance increases
this delay by approximately 0.5ms/nF. The graph below shows the variation of soft-start time for different values of capacitor.
Soft Start Time vs Capacitance from ADJ pin to Ground
10
Soft Start time (ms)
8
6
4
2
0
0
5
10
15
20
25
Capacitance (nF)
Actual operating waveforms [VIN=15V, RS=0.1V, L=33µH, 0nF on ADJ]
Soft-start operation. Output current (Ch2) and LX voltage (Ch1)
The trace above shows the typical soft startup time (tSS) of 500µs with no additional capacitance added to the ADJ pin.
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Application Information (cont.)
This time has been extended on the trace below by adding a 100nF ceramic capacitor which gives a soft start time of
40 milliseconds approximately.
Actual operating waveforms [VIN=15V, RS=0.1V, L=33μH, 100nF on ADJ]
Soft-start operation. Output current (CH2) and LX voltage (Ch1)
Inherent open-circuit LED protection
If the connection to the LED(s) is open-circuited, the coil is isolated from the LX pin of the chip, so the device will not be
damaged, unlike in many boost converters, where the back EMF may damage the internal switch by forcing the drain above
its breakdown voltage.
Capacitor selection
A low ESR capacitor should be used for input decoupling, as the ESR of this capacitor appears in series with the supply
source impedance and lowers overall efficiency. This capacitor has to supply the relatively high peak current to the coil and
smooth the current ripple on the input supply. A minimum value of 4.7μF is acceptable if the input source is close to the
device, but higher values will improve performance at lower input voltages, especially when the source impedance is high.
The input capacitor should be placed as close as possible to the IC.
For maximum stability over temperature and voltage, capacitors with X7R, X5R, or better dielectric are recommended.
Capacitors with Y5V dielectric are not suitable for decoupling in this application and should NOT be used.
A suitable Murata capacitor would be GRM42-2X7R475K-50.
The following web sites are useful when finding alternatives:
www.murata.com
www.t-yuden.com
www.kemet.com
www.avxcorp.com
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Application Information (cont.)
Inductor Selection
Recommended inductor values for the ZXLD1360 are in the range 33µH to 100µH.
Higher values of inductance are recommended at higher supply voltages in order to minimize errors due to switching delays,
which result in increased ripple and lower efficiency. Higher values of inductance also result in a smaller change in output
current over the supply voltage range. (See graphs). The inductor should be mounted as close to the device as possible with
low resistance connections to the LX and VIN pins.
The chosen coil should have a saturation current higher than the peak output current and a continuous current rating above
the required mean output current.
Suitable coils for use with the ZXLD1360 are listed in the table below:
Part No.
MSS1038-333
MSS1038-683
NPIS64D330MTRF
L
(µH)
33
68
33
DCR
(V)
0.093
0.213
0.124
ISAT
(A)
2.3
1.5
1.1
Manufacturer
CoilCraft www.coilcraft.com
NIC www.niccomp.com
The inductor value should be chosen to maintain operating duty cycle and switch 'on'/'off' times within the specified limits over
the supply voltage and load current range.
The following equations can be used as a guide, with reference to Figure 1 - Operating waveforms.
LX Switch ‘On’ time
t ON =
VIN − VLED
LΔI
− Iavg × (R S + rL + RLX )
Note: tONmin > 240ns
t OFF =
LΔI
VLED + VD + Iavg × (R S + rL )
Note: tOFFmin > 200ns
Where:
L is the coil inductance (H)
rL is the coil resistance (Ω)
RS is the current sense resistance (Ω)
Iavg is the required LED current (A)
ΔI is the coil peak-peak ripple current (A) {Internally set to 0.3 x Iavg}
VIN is the supply voltage (V)
VLED is the total LED forward voltage (V)
RLX is the switch resistance (Ω) {=0.5Ω nominal}
VD is the diode forward voltage at the required load current (V)
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Application Information (cont.)
Example:
For VIN =12V, L=33µH, rL=0.093, RS=0.1Ω , RLX=0.15Ω, VLED=3.6V, Iavg =1A and VD =0.49V
tON = (33e-6 x 0.3)/(12 - 3.6 - 0.693) = 1.28µs
tOFF = (33e-6 x 0.3)/(3.6 + 0.49 + 0.193) = 2.31µs
This gives an operating frequency of 280kHz and a duty cycle of 0.35.
These and other equations are available as a spreadsheet calculator from the Diodes website at www.diodes.com
Note that, in practice, the duty cycle and operating frequency will deviate from the calculated values due to dynamic switching
delays, switch rise/fall times and losses in the external components.
Optimum performance will be achieved by setting the duty cycle close to 0.5 at the nominal supply voltage. This helps to
equalize the undershoot and overshoot and improves temperature stability of the output current.
Diode selection
For maximum efficiency and performance, the rectifier (D1) should be a fast low capacitance Schottky diode with low reverse
leakage at the maximum operating voltage and temperature.
They also provide better efficiency than silicon diodes, due to a combination of lower forward voltage and
reduced recovery time.
It is important to select parts with a peak current rating above the peak coil current and a continuous current rating higher
than the maximum output load current. It is very important to consider the reverse leakage of the diode when operating above
85°C. Excess leakage will increase the power dissipation in the device and if close to the load may create a thermal runaway
condition.
The higher forward voltage and overshoot due to reverse recovery time in silicon diodes will increase the peak voltage on the
LX output. If a silicon diode is used, care should be taken to ensure that the total voltage appearing on the LX pin including
supply ripple, does not exceed the specified maximum value.
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Application Information (cont.)
Reducing Output Ripple
Peak to peak ripple current in the LED(s) can be reduced, if required, by shunting a capacitor Cled across the LED(s) as
shown below:
Rs
VIN
LED
Cled
L1
D1
VIN
ISENSE
LX
ZXLD1360
A value of 1µF will reduce the supply ripple current by a factor three (approx.). Proportionally lower ripple can be achieved
with higher capacitor values. Note that the capacitor will not affect operating frequency or efficiency, but it will increase startup delay, by reducing the rate of rise of LED voltage.
By adding this capacitor the current waveform through the LED(s) changes from a triangular ramp to a more sinusoidal
version without altering the mean current value.
Operation at low supply voltage
The internal regulator disables the drive to the switch until the supply has risen above the start-up threshold (VSU). Above this
threshold, the device will start to operate. However, with the supply voltage below the specified minimum value, the switch
duty cycle will be high and the device power dissipation will be at a maximum. Care should be taken to avoid operating the
device under such conditions in the application, in order to minimize the risk of exceeding the maximum allowed die
temperature. (See next section on thermal considerations). The drive to the switch is turned off when the supply voltage falls
below the under-voltage threshold (VSD). This prevents the switch working with excessive 'on' resistance under conditions
where the duty cycle is high.
Note that when driving loads of two or more LEDs, the forward drop will normally be sufficient to prevent the device from
switching below approximately 6V. This will minimize the risk of damage to the device.
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Application Information (cont.)
Thermal considerations
When operating the device at high ambient temperatures, or when driving maximum load current, care must be taken to
avoid exceeding the package power dissipation limits. The graph below gives details for power derating. This assumes the
device to be mounted on a 25mm x 25mm PCB with 1oz copper standing in still air.
Maximum Power Dissipation
1100
1000
900
800
Power (mW)
700
600
500
400
300
200
100
0
-50
-30
-10
10
30
50
70
90
110
130
150
Ambient Temperature (Deg C)
Note that the device power dissipation will most often be a maximum at minimum supply voltage. It will also increase if the
efficiency of the circuit is low. This may result from the use of unsuitable coils, or excessive parasitic output capacitance on
the switch output.
Thermal compensation of output current
High luminance LEDs often need to be supplied with a temperature compensated current in order to maintain stable and
reliable operation at all drive levels. The LEDs are usually mounted remotely from the device so, for this reason, the
temperature coefficients of the internal circuits for the ZXLD1360 have been optimized to minimize the change in output
current when no compensation is employed. If output current compensation is required, it is possible to use an external
temperature sensing network - normally using Negative Temperature Coefficient (NTC) thermistors and/or diodes, mounted
very close to the LED(s). The output of the sensing network can be used to drive the ADJ pin in order to reduce output
current with increasing temperature.
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Application Information (cont.)
Layout Considerations
LX pin
The LX pin of the device is a fast switching node, so PCB tracks should be kept as short as possible. To minimize ground
'bounce', the ground pin of the device should be soldered directly to the ground plane.
Coil and decoupling capacitors and current sense resistor
It is particularly important to mount the coil and the input decoupling capacitor as close to the device pins as possible to
minimize parasitic resistance and inductance, which will degrade efficiency. It is also important to minimize any track
resistance in series with current sense resistor RS. Its best to connect VIN directly to one end of RS and Isense directly to the
opposite end of RS with no other currents flowing in these tracks. It is important that the cathode current of the Schottky
diode does not flow in a track between RS and VIN as this may give an apparent higher measure of current than is actual
because of track resistance.
ADJ pin
The ADJ pin is a high impedance input for voltages up to 1.35V so, when left floating, PCB tracks to this pin should be as
short as possible to reduce noise pickup. A 100nF capacitor from the ADJ pin to ground will reduce frequency modulation of
the output under these conditions. An additional series 10kΩ resistor can also be used when driving the ADJ pin from an
external circuit (see below). This resistor will provide filtering for low frequency noise and provide protection against high
voltage transients.
10k
ADJ
100nF
ZXLD1360
GND
GND
High voltage tracks
Avoid running any high voltage tracks close to the ADJ pin, to reduce the risk of leakage currents due to board contamination.
The ADJ pin is soft-clamped for voltages above 1.35V to desensitize it to leakage that might raise the ADJ pin voltage and
cause excessive output current. However, a ground ring placed around the ADJ pin is recommended to minimize changes in
output current under these conditions.
Evaluation PCB
A number of ZXLD1360 evaluation boards are available on request for qualified opportunities.
For example:
ZXLD1360EV11 MR16 replacement interfaces to external LED.
The evaluation boards allow quick testing of the ZXLD1360 and provide a simple way of connecting external LEDs.
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Application Information (cont.)
Dimming output current using PWM
Low frequency PWM mode
When the ADJ pin is driven with a low frequency PWM signal (eg 100Hz), with a high level voltage VADJ and a low level of
zero, the output of the internal low pass filter will swing between 0V and VADJ, causing the input to the shutdown circuit to fall
below its turn-off threshold (200mV nom) when the ADJ pin is low. This will cause the output current to be switched on and
off at the PWM frequency, resulting in an average output current IOUTavg proportional to the PWM duty cycle.
(See Figure 3 - Low frequency PWM operating waveforms).
VADJ
Ton
PWM Voltage
Toff
0V
VADJ
Filter Output
300mV
200mV
0V
IOUTnom
0.1/Rs
Output Current
IOUTavg
0
Figure 3. Low frequency PWM operating waveforms
The average value of output current in this mode is given by:
IOUTavg = 0.1DPWM/RS [for DPWM >0.01]
This mode is preferable if optimum LED 'whiteness' is required. It will also provide the widest possible dimming range
(approx. 100:1) and higher efficiency at the expense of greater output ripple.
Note that the low pass filter introduces a small error in the output duty cycle due to the difference between the start-up and
shut-down times. This time difference is a result of the 200mV shutdown threshold and the rise and fall times at the output of
the filter. To minimize this error, the PWM frequency should be as low as possible consistent with avoiding flicker in the
LED(s).
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Application Information (cont.)
High frequency PWM mode
At PWM frequencies above 10kHz and for duty cycles above 0.16, the output of the internal low pass filter will contain a DC
component that is always above the shutdown threshold. This will maintain continuous device operation and the nominal
average output current will be proportional to the average voltage at the output of the filter, which is directly proportional to
the duty cycle. (See Figure 4 – High frequency PWM operating waveforms). For best results, the PWM frequency should be
maintained above the minimum specified value of 10kHz, in order to minimize ripple at the output of the filter. The shutdown
comparator has approximately 50mV of hysteresis, to minimize erratic switching due to this ripple. An upper PWM frequency
limit of approximately one tenth of the operating frequency is recommended, to avoid excessive output modulation and to
avoid injecting excessive noise into the internal reference.
VADJ
Ton
PWM voltage
Toff
0V
VADJ
Filter output
200mV
0V
0.1/RS
Output current
IOUTnom
0
Figure 4. High Frequency PWM Operating Waveforms
The nominal average value of output current in this mode is given by:
IOUTnom »0.1DPWM/RS [for DPWM >0.16]
This mode will give minimum output ripple and reduced radiated emission, but with a reduced dimming range (approx.5:1).
The restricted dimming range is a result of the device being turned off when the dc component on the filter output falls below
200mV.
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Ordering Information
Part
Mark
1360
Device
ZXLD1360ET5TA
Package Packaging
Code
(Note 4)
ET5
TSOT23-5
Reel size
(mm)
180
Reel width
(mm)
8
Quantity
per reel
3000
Part Number
Suffix
TA
AEC-Q100
Level
Grade 1
Package Outline Diminsions
TSOT23-5
D
e1
E
E1
L2
c
4x θ1
e
L
5x b
A
A2
θ
TSOT23-5
Dim Min Max Typ
A
− 1.00
−
A1 0.01 0.10
−
A2 0.84 0.90
−
D
2.90
−
−
E
2.80
−
−
E1
1.60
−
−
b 0.30 0.45
−
c 0.12 0.20
−
e
0.95
−
−
e1
1.90
−
−
L 0.30 0.50
L2
0.25
−
−
θ
0°
8°
4°
θ1
4°
12°
−
All Dimensions in mm
A1
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IMPORTANT NOTICE
DIODES INCORPORATED MAKES NO WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, WITH REGARDS TO THIS DOCUMENT,
INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
(AND THEIR EQUIVALENTS UNDER THE LAWS OF ANY JURISDICTION).
Diodes Incorporated and its subsidiaries reserve the right to make modifications, enhancements, improvements, corrections or other changes
without further notice to this document and any product described herein. Diodes Incorporated does not assume any liability arising out of the
application or use of this document or any product described herein; neither does Diodes Incorporated convey any license under its patent or
trademark rights, nor the rights of others. Any Customer or user of this document or products described herein in such applications shall assume
all risks of such use and will agree to hold Diodes Incorporated and all the companies whose products are represented on Diodes Incorporated
website, harmless against all damages.
Diodes Incorporated does not warrant or accept any liability whatsoever in respect of any products purchased through unauthorized sales
channel.
Should Customers purchase or use Diodes Incorporated products for any unintended or unauthorized application, Customers shall indemnify and
hold Diodes Incorporated and its representatives harmless against all claims, damages, expenses, and attorney fees arising out of, directly or
indirectly, any claim of personal injury or death associated with such unintended or unauthorized application.
Products described herein may be covered by one or more United States, international or foreign patents pending. Product names and markings
noted herein may also be covered by one or more United States, international or foreign trademarks.
LIFE SUPPORT
Diodes Incorporated products are specifically not authorized for use as critical components in life support devices or systems without the express
written approval of the Chief Executive Officer of Diodes Incorporated. As used herein:
A. Life support devices or systems are devices or systems which:
1. are intended to implant into the body, or
2. support or sustain life and whose failure to perform when properly used in accordance with instructions for use provided in the
labeling can be reasonably expected to result in significant injury to the user.
B. A critical component is any component in a life support device or system whose failure to perform can be reasonably expected to cause the
failure of the life support device or to affect its safety or effectiveness.
Customers represent that they have all necessary expertise in the safety and regulatory ramifications of their life support devices or systems, and
acknowledge and agree that they are solely responsible for all legal, regulatory and safety-related requirements concerning their products and
any use of Diodes Incorporated products in such safety-critical, life support devices or systems, notwithstanding any devices- or systems-related
information or support that may be provided by Diodes Incorporated. Further, Customers must fully indemnify Diodes Incorporated and its
representatives against any damages arising out of the use of Diodes Incorporated products in such safety-critical, life support devices or
systems.
Copyright © 2011, Diodes Incorporated
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