MPD LDM1210700 Ldm12-xx-xxx Datasheet

LDM12-xx-xxx
Miniature, Wide Input
Constant Current
DC/DC LED Drivers
Electrical Specifications
Specifications typical @ +25°C, nominal input voltage & rated output current, unless otherwise noted. Specifications subject to change without notice.
Key Features:
Input
Parameter
• Constant Current Output
Input Voltage Range
• Wide 7V to 16V Input Range Maximum Input Voltage
Input Filter
• 93% Efficiency
Output
• Miniature MiniDIP Case
Parameter
Output Voltage Range
• 300 mA to 1A Output
Output Current
• Meets EN 60950
Output Current Accuracy
Output Power
• 3.3 MHrs MTBF
Efficiency
• Digital & Analog Dimming! Capacitive Load
Operating Frequency
Ripple & Noise (20 MHz)
Temperature Coefficient
Thermal Impedance
Output Short Circuit
Environmental
Parameter
Conditions
Typ.
12
Max.
16.0
20.0
Units
VDC
VDC
Min.
Typ.
VIN = 16V
2
See Model Selection Guide
See Model Selection Guide
See Model Selection Guide
See Model Selection Guide
Max.
14
Units
VDC
47
400
µF
kHz
±0.03
%/ºC
ºC/W
Max.
+85
+105
+125
Units
95
260
%
ºC
0.5 Sec
Internal Capacitor
Conditions
60
See Model Selection Guide
Natural Convection
+35
Regulated At Rated Output Current
Conditions
Ambient
Case
Operating Temperature Range
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Stoughton, MA 02072
USA
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Min.
7.0
Storage Temperature Range
Cooling
Humidity
Lead Temperature (Solder)
Physical
Case Size
Case Material
Weight
Remote On/Off Control
Parameter
DC/DC On
DC/DC Off
Remote Pin Drive Current
Quiescent Input Current (Shutdown Mode)
PWM Dimming
Parameter
Operation Frequency
Switch On Time
Switch Off Time
Analog Dimming
Parameter
Input Voltage Range
Output Current Adjustment
Control Voltage Range Limits
Drive Current
EMC Compliance
EMI/RFI
Electrostatic Discharge (ESD)
RF Field Susceptibility
Electrical Fast Transients/Bursts On Mains
EMS Immunity
Reliability Specifications
Parameter
MTBF
Min.
-40
Typ.
+25
-40
Free Air Convection
RH, Non-condensing
1.5 mm From Case For 10 Sec
ºC
ºC
0.50 x 0.40 x 0.27 Inches (12.70 x 10.16 x 6.85 mm)
Non-Conductive Black Plastic (UL94-V0)
0.064 Oz (1.8g)
Conditions
Min.
VADJ = 1.25V
VIN = 16V
Conditions
Recommended Maximum
Min.
Typ.
Max.
Units
Open or 0.3V < VADJ <1.25V
VADJ <0.15V
1
mA
25
µA
Typ.
Max.
1.0
Units
kHz
nS
nS
Typ.
Max.
1.25
100
1.25
0.15
1.0
Units
VDC
%
200
200
Conditions
At VADJ Input (Pin 7)
On
Off
VADJ = 1.25V
Min.
0.0
25
0.30
0.0
Radiated/Conducted
Class A
Class A
Class A
Conditions
MIL HDBK 217F, 25ºC, Gnd Benign
VDC
mA
EN 55015 (CISPR22)
IEC/EN 61000-4-2, -6, -8
IEC/EN 61000-4-3
IEC/EN 61000-4-4
EN61547
Min.
3.3
Typ.
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Max.
Units
MHours
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Model Selection Guide
Input
Model
Number
LDM12-04-300
LDM12-05-350
LDM12-07-500
LDM12-08-600
LDM12-10-700
LDM12-14-1000
Output
Voltage (VDC)
Range
7.0 - 16.0
7.0 - 16.0
7.0 - 16.0
7.0 - 16.0
7.0 - 16.0
7.0 - 16.0
Voltage (VDC)
Range
2.0 - 14.0
2.0 - 14.0
2.0 - 14.0
2.0 - 14.0
2.0 - 14.0
2.0 - 14.0
Notes:
1. A reversed power source could damage the unit.
2. No connection should be made between input ground and the output.
3. These are step-down devices, the maximum output open voltage is
equal to the input voltage.
Current
Max (mA)
300
350
500
600
700
1,000
Accuracy (%)
±5
±6
±7
±7
±7
±8
Maximum
Power
Ripple &
Noise
(W)
(mV P-P, Max)
4.2
4.9
7.0
8.4
9.8
14.0
120
150
200
200
250
250
Efficiency
Package
(%, Typ)
93
93
93
93
93
93
8 -Pin MiniDIP
8 -Pin MiniDIP
8 -Pin MiniDIP
8 -Pin MiniDIP
8 -Pin MiniDIP
8 -Pin MiniDIP
4. The VADJ input should be left open if not used. Grounding VADJ will shut the unit
down. Connecting VADJ to VIN may damage the unit.
5. Exceeding the specified maximum output power could cause damage to the unit.
Typical Connection: DC/DC Input
Connection Notes:
To comply with EN61000-4-5, a TVS should be installed before the input filter components. A 3.0SMCJ15A or SMCJ16A is recommended. The TVS max clamping voltage (@max peak pulse
current VC) must be ⬉20V. This will prevent any surge from exceeding the maximum input of the driver (20 VDC). Exceeding the maximum input rating could damage the driver.
The filter shown (C1, C2, C3 and L1) will help to meet conducted emission requirements. With the addition of the filter, the unit should meet the levels of EN 55015.
Typical Connection: AC/DC Input
Connection Notes:
This is a distributed (or two-stage) AC connection. In this configuration, the AC line in (85 to 264 VAC) is connected to the MPM-20S-15EPB, a compact 20W AC/DC
power supply. The MPM-20S-15EPB provides a tightly regulated 15 VDC output at 1,330 mA. The 15 VDC output powers the LED driver.
The two stage approach can simplify the safety approval process (most AC/DC power supplies on the market are approved to EN 60950) and may increase design flexibility. Besides the output voltage/current ratings, other specifications to consider when selecting the input AC/DC supply might include input range, case size, efficiency,
EMI ratings and operating temperature range.
Note: The output current adjustment circuit shown in both connection diagrams is discussed on page 4.
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PWM Output Current Control
An LED operates at its maximum efficiency when
operated at the rated drive current specified by
the manufacturer. Operating an LED at lower than
its rated forward current not only decreases the
system efficiency; but may cause color (or wavelength) shifting. In illumination applications, this
could cause visible changes to lighting.
A preferred method is using pulse width modulation (PWM). As shown at left, the output current
is adjusted by applying a PWM signal to the VADJ
input. By varying the signal duty cycle the average
output current is adjusted up or down. To avoid
visible flicker, the PWM signal should be greater
than 200 Hz.
For duty cycles (DPWM) between 0.1 and 1, the
output current is derived by the formula:
PWM Control Signals
INOM = IMAX X DPWM
The VADJ input may be driven via an open collector transistor (as shown). The diode and resistor
suppress high amplitude negative spikes that may
be caused by the drain-source capacitance of the
transistor. Negative spikes on the control input of
the unit could cause errors in output current or
erratic operation.
The VADJ input can also be driven by the open drain
output of a microcontroller. Again, any high amplitude
negative spikes that may be caused by the drainsource capacitance of the FET must be supressed.
PWM Dimming Application
A simple method of achieving digital (or PWM) dimming is by using a 555 timer
to apply a series of pulses to the VADJ input, as illustrated above. The 555 operates over a supply voltage range of 4.5 VDC to 18VDC. Here it is connected
to the 15 VDC output of the SR7805 switching regulator (this is also the VIN
of the LED driver). Care should be taken to minimize ripple at the VCC input.
Excess ripple could cause timing errors.
again. The formulas for calculating the frequency and duty cycle are included
in the MPD application note “Driving LEDs”.
The diodes (D1 and D2) allow duty cycles below 50% to be set. Diode D1
bypasses R2 while C4 is charging. Diode D2 is optional (but recommended),
essentially blocking R2 during the charge period. Theoretically, this circuit will
allow for duty cycles over a range of approximately 5% to 95%. If manual
The timer is connected for astable (free run) operation. The frequency is set adjustment is desired, a potentiometer may be substituted for R2 (with some
by R1, R2 and C4. The timing capacitor (C4) charges through R1 and D2. When adjustment of the circuit).
it reaches the level of 2/3 VCC, the discharge pin (pin 7) goes low and C4 will
discharge through D1 and R2 to the internal discharge transistor. When the C4 The size of C4 is generally not critical, but it should be as low leakage as posvoltage drops to 1/3 VCC, the discharge pin goes high and C4 begins to charge sible. In order to avoid excessive current flow through the internal discharge
transistor, it is recommended that R1 be at least 5 k⍀.
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Analog Output Current Control (VCNT = 5V)
The output current of the unit can also
be set by adjusting the voltage level on
the VADJ input to a value between 0.3V to
1.25V (IOUT will vary from 25% to 100% of
rated output current). Care must be taken
not to exceed 1.25V on this input, or the
driver may be damaged.
A simple analog circuit using two low
cost, switching regulators is shown at
left. Working from inputs that can range
from 20 to 32 VDC,the top regulator
(SR1) keeps the input to the LED driver
at 15 VDC.
The other regulator (SR2), driven off the same input line maintains
the control voltage (for the VADJ input) at 5 VDC. The resister
network of R1 and R2 can now be used to set the output current
level of the LED driver. This level is equal to:
VADJ =
Analog Output Current Control (5 - 16 VDC IN)
R2 X V
CTRL
R1 + R 2
In the second circuit, the 5 VDC regulator
(SR2) is replaced by the shunt regulator (D1)
circuit connected in parallel with the resistor network. The regulator will maintain
the voltage across R2 and R3 at 2.5 VDC,
insuring that the 1.25 VDC limit on the VADJ
pin will not be exceeded.
When using the analog control input, the
nominal output current is equal to:
INOM = IMAX x
VADJ
1.25
The VADJ input should be left open if not
used. Grounding VADJ will shut the unit
down. Connecting VADJ to directly to +VIN
may damage the unit.
Mechanical Dimensions
Pin Connections
Pin
Function
1
+VIN
+DC Supply
4
+LED
LED Anode Conn.
5
-LED LED Cathode Conn.
7
VADJ
PWM, On/Off
8
-VIN
-DC Supply
Get a full explanation of the
circuits in this datasheet and
more in “Driving LEDs”.
Available free at the MPD website
Notes:
• All dimensions are typical in inches (mm)
• Tolerance x.xx = ±0.02 (±0.50)
• Pin 1 is marked by a “dot” or indentation on the top of the unit
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•
TEL: (781) 344-8226
•
FAX: (781) 344-8481
•
E-Mail: [email protected]
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