IKSEMICON IL1084-5.0

TECHNICAL DATA
IL1084-XX
5A LOW DROPOUT POSITIVE REGULATOR
Features
•
Output Current : 5A
•
Maximum Input Voltage : 12V
•
Adjustable Output Voltage or Fixed
•
1.8V, 3.3V, 5.0V
•
Current Limiting and Thermal Protection
•
Standard 3-Pin Power Packages
Applications
•
Post Regulator for Switching DC/DC Converter
•
High Efficiency Liner Regulators
•
Battery Charger
TA = -10 to 125°C
Absolute Maximum Ratings
Symbol
VI
Tstg
Top
Parameter
DC Input Voltage
Storage Temperature Range
Operating Junction Temperature Range
(Note 3)
Value
12
-65 to +150
-10 to +125
Unit
V
°C
°C
Absolute Maximum Ratings are those values beyond which damage to the device may occur. Functional operation under these
condition is not implied.
Rev. 04
IL1084-xx
Thermal Data
Symbol
θjc
θja
Parameter
TO-220
TO-263
TO-252
Unit
3
50
3
62.5
3
50
°C/W
°C/W
Thermal Resistance Junction-case
Thermal Resistance Junction-ambient
Apllication Circuit
Rev. 04
IL1084-xx
ELECTRICAL CHARACTERISTICS
Typicals and limits appearing in normal type apply for Tj= +25°C.
Limits appearing in Boldface type apply over the entire junction temperature range for operation.
Symbol
Parameter
Output Voltage
VOUT
Conditions
Min
Typ
Max
(Note 5)
(Note 4)
(Note 5)
1.250
1.250
1.263
1.268
(Note 6)
IOUT=10mA,VIN=4.25V
0≤IOUT≤IFULL LOAD, 2.75V≤VIN≤10V
1.237
1.232
IL1084-1.8 BT2
IOUT=10mA,VIN=4.8V
0≤IOUT≤IFULL LOAD, 3.3V≤VIN≤10V
1.782
1.773
IL1084-3.3 BT2
IOUT=10mA,VIN=6.3V
0≤IOUT≤IFULL LOAD, 4.8V≤VIN≤10V
3.270
3.250
IL1084-5.0 BT2
IOUT=10mA,VIN=8.0V
0≤IOUT≤IFULL LOAD, 6.5V≤VIN≤10V
4.950
4.925
5.000
5.000
5.050
5.075
4.900
5.000
5.100
IL1084-Adj BT2
1.225
1.764
3.235
1.250
1.800
1.800
1.800
3.300
3.300
3.300
Units
1.275
1.818
1.827
1.836
3.330
3.350
3.365
Rev. 04
IL1084-xx
ELECTRICAL CHARACTERISTICS
Typicals and limits appearing in normal type apply for Tj= +25°C.
Limits appearing in Boldface type apply over the entire junction temperature range for operation.
Symbol
Min
Typ
Max
(Note 5)
(Note 4)
(Note 5)
-
-
VIN=8.0V, 0≤IOUT≤IFULL LOAD
-
-
∆VREF=1%, IOUT=5A
VIN=10V
VIN=6.25V
VIN=2.75÷10V,IOUT=10mA
IOUT=10mA÷5A, VIN=2.75÷10V
fRIPPLE = 120Hz, COUT=25µF
Tantalum, Iout=5A;VIN=4.25V
5.5
-
-
0.3
0.4
6
10
6
10
6
10
0.3
0.4
12
20
15
20
20
35
1.5
10
120
5
60
-
-
dB
-
0.5
-
%
Parameter
Conditions
Line Regulation (Note 7)
IL1084-Adj BT2
IOUT=10mA, 2.75V≤VIN≤10V
IL1084-1.8 BT2
IOUT=10mA, 3.3V≤VIN≤10V
IL1084-3.3 BT2
IOUT=10mA, 4.8V≤VIN≤10V
IL1084-5.0 BT2
IOUT=10mA, 6.5V≤VIN≤10V
Load Regulation (Note 7)
IL1084-Adj BT2
VIN=4.25V, 0≤IOUT≤IFULL LOAD
IL1084-1.8 BT2
VIN=5.0V, 0≤IOUT≤IFULL LOAD
IL1084-3.3 BT2
VIN=5.0V, 0≤IOUT≤IFULL LOAD
IL1084-5.0 BT2
∆V
IO(MIN)
ILIMIT
IADJ
∆IADJ
Dropout Voltage (Note 8)
Minimum Load Current
Current Limit
Adjust Pin Current
Adjust Pin Current Change
RR
Ripple Rejection
S
Temperature Stability
∆VOUT
∆VOUT
Units
%
%
mV
V
mA
A
µA
µA
NOTES 1: Rating indicate conditions for which the device is intended to be functional, but specific performance is not Guaranteeed.
For guaranteed specifications and the test conditions, see the Electrical Characteristics.
NOTES 2: Power Dissipation is kept in a safe range by current limiting circuitry. Refer to Overload Recovery
in Application Notes.
NOTES 3: The maximum power dissipation is a function of Tj(MAX), ΘjA and TA . The maximu allowable power dissipation at any ambient
temperature is PD=(Tj(MAX) – TA)ΘjA .
NOTES 4: Typical Values represent the most likely parametric norm
NOTES 5: All limits are guaranteed by testing or statistical analysis
NOTES 6: IFULL LOAD is defind in the current limit curves . The IFULL LOAD curve defines the current limit as function
NOTES 7: Load and Line regulation are measured at constant junction temperature , and are guaranteed up to the maximum power
dissipation of 30W.Power dissipation is determined by the input/output differential and the output current. Guaranteed maximum power
dissipation will not be available over the full input/output range.
NOTES 8: Dropout voltage is specified over the full output current range of the device
Rev. 04
IL1084-xx
TYPICAL CHARACTERISTICS
(unless otherwise specified Tj = 25°C, CI=10µF (tant.), CO=10µF (tant.)
Dropout Voltage vs Output Current
Line Regulation vs Temperature
Dropout Voltage vs Temperature
Output Voltage vs Temperature
Short Circuit Current vs Dropout
Load Regulation vs Temperature
Voltage
Rev. 04
IL1084-xx
TYPICAL CHARACTERISTICS
Supply Voltage Rejection vs Frequency
Adjust Pin Current vs Output Current
Rev. 04
IL1084-xx
Application Note
GENERAL
Figure 1 shows a basic functional diagram for the IL1084-Adj (excluding protection circuitry) . The topology is basically
that of the LM317 except for the pass transistor. Instead of a Darlingtion NPN with its two diode voltage drop, the IL1084
uses a single NPN. This results in a lower dropout voltage. The structure of the pass transistor is also known as a quasi
LDO. The advantage a quasi LDO over a PNP LDO is its inherently lower quiescent current. The IL1084 is guaranteed to
provide a minimum dropout voltage 1.5V over temperature, at full load.
FIGURE 1. Basic Functional Diagram for the IL1084,
excluding Protection circuitry
OUTPUT VOLTAGE
The IL1084 adjustable version develops at 1.25V reference voltage, (VREF), between the output and the adjust terminal.
As shown in figure 2, this voltage is applied across resistor R1 to generate a constant current I1. This constant current
then flows through R2. The resulting voltage drop across R2 adds to the reference voltage to sets the desired output
voltage. The current IADJ from the adjustment terminal introduces an output error . But since it is small (120uA max), it
becomes negligible when R1 is in the 100Ω range. For fixed voltage devices, R1 and R2 are integrated inside the
devices.
FIGURE 2. Basic Adjustable Regulator
STABILITY CONSIDERATION
Stability consideration primarily concern the phase response of the feedback loop. In order for stable operation, the loop
must maintain negative feedback. The IL1084 requires a certain amount series resistance with capacitive loads. This
series resistance introduces a zero within the loop to increase phase margin and thus increase stability. The equivalent
series resistance (ESR) of solid tantalum or aluminum electrolytic capacitors is used to provide the appropriate zero
(approximately 500 kHz).
The Aluminum electrolytic are less expensive than tantalums, but their ESR varies exponentially at cold temperatures;
therefore requiring close examination when choosing the desired transient response over temperature. Tantalums are a
convenient choice because their ESR varies less than 2:1 over temperature.
The recommended load/decoupling capacitance is a 10uF tantalum or a 50uF aluminum. These values will assure
stability for the majority of applications.
The adjustable versions allows an additional capacitor to be used at the ADJ pin to increase ripple rejection. If this is
done the output capacitor should be increased to 22uF for tantalums or to 150uF for aluminum.
Capacitors other than tantalum or aluminum can be used at the adjust pin and the input pin. A 10uF capacitor is a
reasonable value at the input. See Ripple Rejection section regarding the value for the adjust pin capacitor.
It is desirable to have large output capacitance for applications that entail large changes in load current (microprocessors
for example). The higher the capacitance, the larger the available charge per demand. It is also desirable to provide low
ESR to reduce the change in output voltage:
∆V = ∆I x ESR
Rev. 04
IL1084-xx
It is common practice to use several tantalum and ceramic capacitors in parallel to reduce this change in the output
voltage by reducing the overall ESR.
Output capacitance can be increased indefinitely to improve transient response and stability.
RIPPLE REJECTION
Ripple rejection is a function of the open loop gain within the feed-back loop (refer to Figure 1 and Figure 2). The IL1084
exhibits 75dB of ripple rejection (typ.). When adjusted for voltages higher than VREF, the ripple rejection decreases as
function of adjustment gain: (1+R1/R2) or VO/VREF. Therefore a 5V adjustment decreases ripple rejection by a factor of
four (−12dB); Output ripple increases as adjustment voltage increases.
However, the adjustable version allows this degradation of ripple rejection to be compensated. The adjust terminal can
be bypassed to ground with a capacitor (CADJ). The impedance of the CADJ should be equal to or less than R1 at the
desired ripple frequency. This bypass capacitor prevents ripple from being amplified as the output voltage is increased.
LOAD REGULATION
The IL1084 regulates the voltage that appears between its output and ground pins, or between its output and adjust pins.
In some cases, line resistances can introduce errors to the voltage across the load. To obtain the best load regulation, a
few precautions are needed.
Figure 3 shows a typical application using a fixed output regulator. Rt1 and Rt2 are the line resistances. VLOAD is less
than the VOUT by the sum of the voltage drops along the line resistances. In this case, the load regulation seen at the
RLOAD would be degraded from the data sheet specification. To improve this, the load should be tied directly to the output
terminal on the positive side and directly tied to the ground terminal on the negative side.
FIGURE 3. Typical Application using Fixed Output Regulator
When the adjustable regulator is used (Figure 4), the best performance is obtained with the positive side of the resistor
R1 tied directly to the output terminal of the regulator rather than near the load. This eliminates line drops from appearing
effectively in series with the reference and degrading regulation. For example, a 5V regulator with 0.05Ω resistance
between the regulator and load will have a load regulation due to line resistance of 0.05 Ω x IL. If R1 (=125 Ω) is
connected near the load the effective line resistance will be 0.05 Ω (1 + R2/R1) or in this case, it is 4 times worse. In
addition, the ground side of the resistor R2 can be returned near the ground of the load to provide remote ground
sensing and improve load regulation.
FIGURE 4. Best Load Regulation using Adjustable Output Regulator
PROTECTION DIODES
Under normal operation, the IL1084 regulator does not need any protection diode. With the adjustable device, the
internal resistance between the adjustment and output terminals limits the current. No diode is needed to divert the
current around the regulator even with a capacitor on the adjustment terminal. The adjust pin can take a transient signal
of ±25V with respect to the output voltage without damaging the device.
Rev. 04
IL1084-xx
When an output capacitor is connected to a regulator and the input is shorted, the output capacitor will discharge into the
output of the regulator. The discharge current depends on the value of the capacitor, the output voltage of the regulator,
and rate of decrease of VIN. In the IL1084 regulator, the internal diode between the output and input pins can withstand
microsecond surge currents of 10A to 20A. With an extremely large output capacitor (≥1000 µf), and with input
instantaneously shorted to ground, the regulator could be damaged. In this case, an external diode is recommended
between the output and input pins to protect the regulator, shown in Figure 5.
FIGURE 5. Regulator with Protection Diode
OVERLOAD RECOVERY
Overload recovery refers to regulator’s ability to recover from a short circuited output. A key factor in the recovery
process is the current limiting used to protect the output from drawing too much power. The current limiting circuit
reduces the output current as the input to output differential increases. Refer to short circuit curve in the curve section.
During normal start-up, the input to output differential is small since the output follows the input. But, if the output is
shorted, then the recovery involves a large input to output differential. Sometimes during this condition the current limiting
circuit is slow in recovering. If the limited current is too low to develop a voltage at the output, the voltage will stabilize at
a lower level. Under these conditions it may be necessary to recycle the power of the regulator in order to get the smaller
differential voltage and thus adequate start up conditions. Refer to curve section for the short circuit current vs. input
differential voltage.
THERMAL CONSIDERATIONS
ICs heats up when in operation, and power consumption is one factor in how hot it gets. The other factor is how well the
heat is dissipated. Heat dissipation is predictable by knowing the thermal resistance between the IC and ambient (θJA).
Thermal resistance has units of temperature per power (C/ W). The higher the thermal resistance, the hotter the IC.
The IL1084 specifies the thermal resistance for each package as junction to case (θJC). In order to get the total
resistance to ambient (θJA), two other thermal resistances must be added, one for case to heat-sink (θCH) and one for
heatsink to ambient (θHA). The junction temperature can be predicted as follows:
TJ is junction temperature, TA is ambient temperature, and PD is the power consumption of the device. Device power
consumption is calculated as follows:
Figure 6 shows the voltages and currents which are present in the circuit.
FIGURE 6. Power Dissipation Diagram
Rev. 04
IL1084-xx
Once the devices power is determined, the maximum allowable (θJA (max)) is calculated as:
θJA (max) = TR(max)/PD = TJ(max) − TA(max)/PD
The IL1084 has different temperature specifications for two different sections of the IC: the control section and the output
section. The Electrical Characteristics table shows the junction to case thermal resistances for each of these sections, while the
maximum junction temperatures (TJ(max)) for each section is listed in the Absolute Maximum section of the datasheet. TJ(max) is
125°C for the control section, while TJ(max) is 150°C for the output section. θJA (max) should be calculated separately for each
section as follows:
θJA (max, CONTROL SECTION) = (125°C - TA(max))/PD
θJA (max, OUTPUT SECTION) = (150°C - TA(max))/PD
The required heat sink is determined by calculating its required thermal resistance (θHA (max)).
(θHA (max)) should also be calculated twice as follows:
(θHA (max)) = θJA (max, CONTROL SECTION) - (θJC (CONTROL SECTION) + θCH)
(θHA (max)) = θJA(max, OUTPUT SECTION) - (θJC (OUTPUT SECTION) + θCH)
If thermal compound is used, θCH can be estimated at 0.2 C/W. If the case is soldered to the heat sink, then a θCH can be
estimated as 0 C/W.
After, θHA (max) is calculated for each section, choose the lower of the two θHA (max) values to determine the appropriate
heat sink.
If PC board copper is going to be used as a heat sink, then Figure 7 can be used to determine the appropriate area (size)
of copper foil required.
FIGURE 7. Heat sink thermal Resistance vs Area
Rev. 04
IL1084-xx
TYPICAL
APPLICATIONS
5V to 3.3V, 5A Regulator
Battery Charger
Adjustable @ 5V
Adjustable Fixed Regulator
1.2V to 15V Adjustable Regulator
Regulator with Reference
5V Regulator with Shutdown
High Current Lamp Driver Protection
Rev. 04
IL1084-xx
TYPICAL
APPLICATIONS (Continued)
Battery Backup Regulated Supply
Automatic Light control
Ripple Rejection Enhancement
Generating Negative Supply voltage
Remote Sensing
Rev. 04
IL1084-xx
Rev. 04
IL1084-xx
Rev. 04
IL1084-xx
TO-263-2L PACKAGE OUTLINE DIMENSION
Rev. 04