AMS AMS1505

AMS1505
General Description
Features
The AMS1505 series of adjustable and fixed low
dropout voltage regulators are designed to provide 5A
output current to power the new generation of
microprocessors. The dropout voltage of the device is
100mV at light loads and rising to 500mV at maximum
output current. A second low current input voltage 1V
or greater then the output voltage is required to
achieve this dropout. The AMS1505 can also be used
as a single supply device.
New features have been added to the AMS1505: a
remote Sense pin is brought out virtually eliminating
output voltage variations due to load changes. The
typical load regulation, measured at the Sense pin, for
a load current step of 100mA to 5A is less than 1mV.
The AMS1505 series has fast transient response. The
Adjust pin is brought out on fixed devices. To further
improve the transient response the addition of a small
capacitor on the Adjust pin is recommended.
The AMS1505 series are ideal for generating
processor supplies of 2V to 3V on motherboards
where both 5V and 3.3V supplies are available.
• Adjustable or Fixed Output
1.5V, 2.5V, 2.85V, 3.0V, 3.3V, 3.5V and 5.0V
• Output Current of 5A
• Low Dropout, 500mV at 5A Output Current
• Fast Transient Response
• Remote Sense
• Adjustable or Fixed Output
Applications
• High Current Regulators
• Post Regulators for Switching Supplies
• Adjustable Power Supply
• Notebook/Personal Computer Supplies
The AMS1505 devices are offered in 5 lead TO-220,
5L TO-263 (plastic DD) and 5L TO-252 (DPAK)
packages.
Typical Application
VCONTROL
+
CONTROL
POWER OUTPUT
VPOWER
+
VOUT
+
AMS1505
SENSE
ADJ
R1
R2
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AMS1505
Absolute Maximum Ratings (Note 1)
Thermal Resistance
Vpower Input Voltage………………………………………..…..……...………….……7V
Vcontrol Input Voltage……………………………………………..….………….……13V
Operating Junction Temperature
Control Section…………………………………….…….……..0°C to +125°C
Power Transistor…………………….………………………...0°C to +150°C
Storage Temperature………………………………….……..…...-65°C to +150°C
Soldering Lead Temperature (10 sec.) ……………...…….………...……300°C
TO-252 package……………………………..….......….……………θJA= 92°C/W
TO-220 package……………………………..….......….……………θJA= 50°C/W
TO-263 package……………………………..….......….…………θJA= 30°C/W*
* With package soldering to 0.5 in2 copper area over backside
ground plane or internal power plane θJA can vary from 20°C/W
to > 40°C/W depending on mounting technique.
Electrical Characteristics
Electrical Characteristics at TA = 25ºC, IOUT = 0 mA unless otherwise specified.
Parameter
Device
Conditions
Min.
Typ.
Max.
Units
Reference
Voltage
AMS1505
VCONTROL = 2.75V, VPOWER =2V, ILOAD = 10mA
VCONTROL = 2.7V to 12V, VPOWER =3.3V to 5.5V,
ILOAD = 10mA to 5A
1.243
1.237
1.250
1.250
1.258
1.263
V
V
Output
Voltage
AMS1505-1.5
VCONTROL = 4V, VPOWER =2.V, ILOAD = 0mA
VCONTROL = 3V, VPOWER =2.3V, ILOAD = 0mA to 5A
1.491
1.485
1.500
1.500
1.509
1.515
V
V
AMS1505-2.5
VCONTROL = 5V, VPOWER =3.3V, ILOAD = 0mA
VCONTROL = 4V, VPOWER =3.3V, ILOAD = 0mA to 5A
2.485
2.475
2.500
2.500
2.515
2.525
V
V
AMS1505-2.85
VCONTROL = 5.35V, VPOWER =3.35V, ILOAD = 0mA
VCONTROL = 4.4V, VPOWER =3.7V, ILOAD = 0mA to 5A
2.821
2.833
2.850
2.850
2.879
2.867
V
V
AMS1505-3.0
VCONTROL = 5.5V, VPOWER =3.5V, ILOAD = 0mA
VCONTROL = 4.5V, VPOWER =3.8V, ILOAD = 0mA to 5A
2.982
2.970
3.000
3.000
3.018
3.030
V
V
AMS1505-3.3
VCONTROL = 5.8V, VPOWER =3.8V, ILOAD = 0mA
VCONTROL = 4.8V, VPOWER =4.1V, ILOAD = 0mA to 5A
3.280
3.235
3.300
3.300
3.320
3.333
V
V
AMS1505-3.5
VCONTROL = 6V, VPOWER =4V, ILOAD = 0mA
VCONTROL = 5V, VPOWER =4.3V, ILOAD = 0mA to 5A
3.479
3.430
3.500
3.500
3.521
3.535
V
V
AMS1505-5.0
VCONTROL = 7.5V, VPOWER =5.5V, ILOAD = 0mA
VCONTROL = 6.5V, VPOWER =5.8V, ILOAD = 0mA to 5A
4.930
4.950
5.000
5.000
5.030
5.050
V
V
Line
Regulation
AMS1505/-1.5/-2.5/
ILOAD = 10 mA , 1.5V≤ (VCONTROL - VOUT) ≤ 12V
1
3
mV
-2.85/ -3.0/-3.3/-3.5/-5.0
0.8V≤ (VPOWER - VOUT) ≤ 5.5V
Load
Regulation
AMS1505/-1.5/-2.5/
VCONTROL = VOUT + 2.5V, VPOWER =VOUT + 0.8V,
1
5
mV
-2.85/-3.0/-3.3/-3.5/-5.0
ILOAD = 10mA to 5A
Minimum Load
Current
AMS1505
VCONTROL = 5V, VPOWER =3.3V, VADJ = 0V (Note 3)
5
10
mA
Control Pin
Current
(Note 4)
AMS1505/-1.5/-2.5/
VCONTROL = VOUT + 2.5V, VPOWER =VOUT + 0.8V,
50
85
mA
-2.85/-3.0/-3.3/-3.5/-5.0
ILOAD = 10mA to 5A
Ground Pin
Current
(Note 4)
AMS1505-1.5/-2.5/
VCONTROL = VOUT + 2.5V, VPOWER =VOUT + 0.8V,
6
10
mA
-2.85/-3.0/-3.3/-3.5/-5.0
ILOAD = 10mA to 5A
Adjust Pin
Current
AMS1505
VCONTROL = 2.75V, VPOWER = 2.05V, ILOAD = 10mA
50
120
µA
Current Limit
AMS1505/-1.5/-2.5/
(VIN - VOUT) = 5V
7.1
8.0
A
AMS1505/-1.5/-2.5/
VCONTROL = VPOWER = VOUT + 2.5V, VRIPPLE = 1VP-P
60
80
dB
-2.85/-3.0/-3.3/-3.5/-5.0
ILOAD = 2A
-2.85/-3.0/-3.3/-3.5/-5.0
Ripple
Rejection
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AMS1505
Electrical Characteristics Continued (Note 2)
Electrical Characteristics at IOUT = 0 mA, and TJ = +25°C unless otherwise specified.
Parameter
Thermal Regulation
Device
AMS1505
Conditions
TA = 25°C, 30ms pulse
Thermal Resistance
Junction-to-Case
T Package: Control Circuitry/ Power
Transistor
M & D Package: Control Circuitry/ Power
Transistor
Dropout Voltage
Note 2
Control Dropout
(VCONTROL - VOUT)
AMS1505/-1.5/2.5/
Min.
Typ.
Max.
Units
0.002
0.020
%W
0.65/2.70
0.65/2.70
°C/W
°C/W
VPOWER =VOUT + 0.8V, ILOAD = 10mA
1.00
1.15
V
VPOWER =VOUT + 0.8V, ILOAD = 5A
1.15
1.30
V
VCONTROL =VOUT + 2.5V, ILOAD = 10mA
.10
0.17
V
VCONTROL =VOUT + 2.5V, ILOAD = 5A
.45
0.50
V
-2.85/-3.0/-3.3/3.5/-5.0
Power Dropout
(VPOWER - VOUT)
AMS1505/-1.5/2.5/
-2.85/-3.0/-3.3/3.5/-5.0
Parameters identified with boldface type apply over the full operating temperature range.
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. For guaranteed specifications and test
conditions, see the Electrical Characteristics. The guaranteed specifications apply only for the test conditions listed.
Note 2: Unless otherwise specified VOUT = VSENSE. For the adjustable device VADJ = 0V.
Note 3: The dropout voltage for the AMS1505 is caused by either minimum control voltage or minimum power voltage. The specifications
represent the minimum input/output voltage required to maintain 1% regulation.
Note 4: For the adjustable device the minimum load current is the minimum current required to maintain regulation. Normally the current in the
resistor divider used to set the output voltage is selected to meet the minimum load current requirement.
Note 5: The control pin current is the drive current required for the output transistor. This current will track output current with a ratio of about
1:100. The minimum value is equal to the quiescent current of the device.
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AMS1505
Pin Description
Pin Number
Name
1
Sense
2
Adjust/gnd
3
Output
4
Vcontrol
5
Vpower
Description
This pin is the positive side of the reference voltage for the device. With
this pin it is possible to Kelvin sense the output voltage at the load.
This pin is the negative side of the reference voltage for the device. Adding
a small bypass capacitor from the Adjust pin to ground improves the
transient response. For fixed voltage devices the Adjust pin is also brought
out to allow the user to add a bypass capacitor.
For fixed voltage devices this is the bottom of the resistor divider that sets
the output voltage.
This is the power output of the device.
This pin is the supply pin for the control circuitry of the device. The current
flow into this pin will be about 1% of the output current. The voltage at this
pin must be 1.3V or greater than the output voltage for the device to
regulate.
This pin is the collector to the power device of the AMS1505. The output
load current is supplied through this pin. The voltage at this pin must be
between 0.1V and 0.8V greater than the output voltage for the device to
regulate.
Pin Configuration
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AMS1505
REFERENCE VOLTAGE (V)
Typical Performance Characteristics
2.50
2.125
2.0
Θja=50ºC/W
1.75
1.5
Θja=60ºC/W
1.25
1.0
0.75
0.5
0.25
0.0
Θja=90ºC/W
0
25 45 65 85 105 125 145
Ambient Temperature (ºC)
TO-252 Power Dissipation
Still Air 2oz Cu on top Plane
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AMS1505
Applications
The AMS1505 is designed to make use of multiple
power supplies, existing in most systems, to reduce the
dropout voltage. One of the advantages of the two
supply approach is maximizing the efficiency.
The second supply is at least 1V greater than output
voltage and is providing the power for the control
circuitry and supplies the drive current to the NPN
output transistor. This allows the NPN to be driven into
saturation; thereby reducing the dropout voltage by a
VBE compared to conventional designs. For the control
voltage the current requirement is small equal to about
1% of the output current or approximately 15mA for a
5A load. Most of this current is drive current for the NPN
output transistor. This drive current becomes part of the
output current. The maximum voltage on the Control pin
is 13V. The maximum voltage at the Power pin is 7V.
Ground pin current for fixed voltage devices is typical
6mA and is constant as a function of load. Adjust pin
current for adjustable devices is 60µA at 25°C and
varies proportional to absolute temperature.
The improved frequency compensation of AMS1505
permits the use of capacitors with very low ESR. This is
critical in addressing the needs of modern, low voltage
high sped microprocessors. Output voltage tolerances
are tighter and include transient response as part of the
specification. Designed to meet the fast current load
step requirements, the AMS1505 also saves total cost
by needing less output capacitance to maintain
regulation.
Careful design of the AMS1505 has eliminated any
supply sequencing issues associated with a dual supply
system. The output voltage will not turn on until both
supplies are operating. If the control voltage comes up
first, the output current will be limited to a few
milliamperes until the power input voltage comes up. If
power input comes up first the output will not turn on at
all until the control voltage comes up. The output can
never come up unregulated. By tying the control and
power inputs together the AMS1505 can also be
operated as a single supply device. In single supply
operation the dropout will be determined by the
minimum control voltage.
The new features of the AMS1505 require additional
pins over the traditional 3-terminal regulator. Both the
fixed and adjustable versions have remote sense pins,
permitting very accurate regulation of output voltage at
the load, rather than at the regulator.
As a result, over an output current range of 100mA
to 5A with a 2.5V output, the typical load regulation
is less than 1mV. For the fixed voltages the adjust
pin is brought out allowing the user to improve
transient response by bypassing the internal
resistor divider. Optimum transient response is
provided using a capacitor in the range of 0.1µF to
1µF for bypassing the Adjust pin. The value chosen
will depend on the amount of output capacitance in
the system.
In addition to the enhancements mentioned, the
reference accuracy has been improved by a factor
of two with a guaranteed initial tolerance of ±0.6%
at 25°C. This device can hold 1% accuracy over the
full temperature range and load current range,
guaranteed, when combined with ratiometrically
accurate internal divider resistors and operating
with an input/output differential of well under 1V.
Typical applications for the AMS1505 include 3.3V
to 2.5V conversion with a 5V control supply, 5V to
4.2V conversion with a 12V control supply or 5V
to3.6V conversion with a 12V control supply.
Capable of 5A of output current with a maximum
dropout of 0.8V the AMS1505 also has a fast
transient response that allows it to handle large
current changes. The device is fully protected
against
overcurrent
and
overtemperature
conditions.
Grounding and Output Sensing
The AMS1505 allows true Kelvin sensing for both
the high and low side of the load. As a result the
voltage regulation at he load can be easily
optimized. Voltage drops due to parasitic
resistances between the regulator and the load can
be placed inside the regulation loop of the
AMS1505. The advantages of remote sensing are
illustrated in figures 1 through 3.
Figure 1 shows the device connected as a
conventional 3 terminal regulator with the Sense
lead connected directly to the output of the device.
RP is the parasitic resistance of the connections
between the device and the load. Typically RP is
made up of the PC traces and /or connector
resistances (in the case of a modular regulator)
between the regulator and the load. Trace A of
figure 3 illustrates the effect of RP. Very small
resistances cause significant load regulation steps.
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AMS1505
Applications continued
Voltage drops due to RP are not eliminated; they will
add to the dropout voltage of the regulator
regardless of whether they are inside or outside the
regulation loop. The AMS1505 can control the
voltage at the load as long as the input-output
voltage is greater than the total of the dropout
voltage of the device plus the voltage drop across
R P.
Figure 2 shows the device connected to take advantage
of the remote sense feature. The Sense pin and the top
of the resistor divider are connected to the top of the
load; the bottom of the resistor divider is connected to
the bottom of the load.
RP is now connected inside the regulation loop of the
AMS1505 and for reasonable values of RP the load
regulation at the load will be negligible. The effect on
output regulation can be seen in trace B of figure 3.
Stability
The circuit design used in the AMS1505 series
requires the use of an output capacitor as part of
the device frequency compensation. The addition of
150µF aluminum electrolytic or a 22µF solid
tantalum on the output will ensure stability for all
operating conditions. For best frequency response
use capacitors with an ESR of less than 1Ω.
In order to meet the transient requirements of the
load larger value capacitors are needed. Tight
voltage tolerances are required in the power supply.
To limit the high frequency noise generated by the
load high quality bypass capacitors must be used.
In order to limit parasitic inductance (ESL) and
resistance (ESR) in the capacitors to acceptable
limits, multiple small ceramic capacitors in addition
to high quality solid tantalum capacitors are
required.
When the adjustment terminal is bypassed to
improve the ripple rejection, the requirement for an
output capacitor increases. The Adjust pin is
brought out on the fixed voltage device specifically
to allow this capability. To ensure good transient
response with heavy load current changes capacitor
values on the order of 100µF are used in the output
of many regulators. To further improve stability and
transient response of these devices larger values of
output capacitor can be used.
The modern systems generate large high frequency
current transients. The load current step contains
higher order frequency components than the output
coupling network must handle until the regulator
throttles to the load current level. Because they
contain parasitic resistance and inductance,
capacitors are not ideal elements. These parasitic
elements dominate the change in output voltage at
the beginning of a transient load step change. The
ESR of the output capacitors produces an
instantaneous step in output voltage (∆V=∆I)(ESR).
Figure 1. Conventional Load Sensing
Figure 2. Remote Load Sensing
(∆IOUT)(RP)
VOUT
FIGURE 1
VOUT
FIGURE 2
IOUT
TIME
Figure 3. Remote Sensing Improves Load
Regulation
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AMS1505
Applications continued
Protection Diodes
Unlike older regulators, the AMS1505 family does
not need any protection diodes between the
adjustment pin and the output and from the output
to the input to prevent die over-stress. Internal
resistors are limiting the internal current paths on
the AMS1505 adjustment pin, therefore even with
bypass capacitors on the adjust pin no protection
diode is needed to ensure device safety under
short-circuit conditions. The Adjust pin can be
driven on a transient basis ±7V with respect to the
output without any device degradation.
Diodes between the Output pin and VPOWER pin are
not usually needed. Microsecond surge currents of
25A to 50A can be handled by the internal diode
between the Output pin and VPOWER pin of the
device. In normal operations it is difficult to get
those values of surge currents even with the use of
large output capacitances. If high value output
capacitors are used, such as 1000µF to 5000µF
and the VPOWER pin is instantaneously shorted to
ground, damage can occur. A diode from output to
input is recommended, when a crowbar circuit at
the input of the AMS1505 is used (Figure 6).
Normal power supply cycling or even plugging and
unplugging in the system will not generate current
large enough to do any damage.
The ESL of the output capacitors produces a droop
proportional to the rate of change of the output current
(V= L)(∆I/∆t). The output capacitance produces a
change in output voltage proportional to the time until
the regulator can respond (∆V=∆t) (∆I/C). Figure 4
illustrates these transient effects.
Figure 4. Transient Response Characteristics
Output Voltage
The AMS1505 series develops a 1.25V reference
voltage between the Sense pin and the Adjust pin
(Figure5). Placing a resistor between these two
terminals causes a constant current to flow through R1
and down through R2 to set the overall output voltage.
In general R1 is chosen so that this current is the
specified minimum load current of 10mA.The current
out of the Adjust pin is small, typically 50µA and it adds
to the current from R1. Because IADJ is very small it
needs to be considered only when very precise output
voltage setting is required. For best regulation the top of
the resistor divider should be connected directly to the
Sense pin.
Figure 6.
Against
Optional
Diodes
Protect
Input Crowbar Circuits
If the AMS1505 is connected as a single supply
device with the control and power input pins shorted
together the internal diode between the output and
the power input pin will protect the control input pin.
As with any IC regulator, none the protection
circuitry will be functional and the internal
transistors will break down if the maximum input to
output voltage differential is exceeded.
VOUT = VREF (1+ R2/R1)+IADJR2
Figure 5. Setting Output Voltage
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AMS1505
Applications continued
Thermal Considerations
The AMS1505 series have internal power and thermal
limiting circuitry designed to protect the device under
overload conditions. However maximum junction
temperature ratings should not be exceeded under
continuous
normal
load
conditions.
Careful
consideration must be given to all sources of thermal
resistance from junction to ambient, including junctionto-case, case-to-heat sink interface and heat sink
resistance itself.
Thermal resistance specification for both the Control
Section and the Power Transistor are given in the
electrical characteristics. The thermal resistance of the
Control section is given as 0.65°C/W and junction
temperature of the Control section can run up to 125°C.
The thermal resistance of the Power section is given as
2.7°C/W and junction temperature of the Power section
can run up to 150°C. Due to the thermal gradients
between the power transistor and the control circuitry
there is a significant difference in thermal resistance
between the Control and Power sections.
Virtually all the power dissipated by the device is
dissipated in the power transistor. The temperature rise
in the power transistor will be greater than the
temperature rise in the Control section making the
thermal resistance lower in the Control section. At
power levels below 12W the temperature gradient will
be less than 25°C and the maximum ambient
temperature will be determined by the junction
temperature of the Control section. This is due to the
lower maximum junction temperature in the Control
section. At power levels above 12W the temperature
gradient will be greater than 25°C and the maximum
ambient temperature will be determined by the Power
section. In both cases the junction temperature is
determined by the total power dissipated in the device.
For most low dropout applications the power dissipation
will be less than 12W.
The power in the device is made up of two components:
the power in the output transistor and the power in the
drive circuit. The power in the control circuit is
negligible.
The power in the drive circuit is equal to:
where ICONTROL is equal to between IOUT/100(typ)
and IOUT/58(max).
The power in the output transistor is equal to:
POUTPUT = (VPOWER -VOUT)(IOUT)
The total power is equal to:
PTOTAL = PDRIVE + POUTPUT
Junction-to-case thermal resistance is specified
from the IC junction to the bottom of the case
directly below the die. This is the lowest resistance
path for the heat flow. In order to ensure the best
possible thermal flow from this area of the package
to the heat sink proper mounting is required.
Thermal compound at the case-to-heat sink
interface is recommended. A thermally conductive
spacer can be used, if the case of the device must
be electrically isolated, but its added contribution to
thermal resistance has to be considered.
PDRIVE = (VCONTROL - VOUT)(ICONTROL)
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AMS1505
Ordering Information
Operating
Junction
Temperature
Range
0 to 125° C
0 to 125° C
0 to 125° C
0 to 125° C
0 to 125° C
0 to 125° C
0 to 125° C
0 to 125° C
Package Type
5 LEAD TO-263
5 LEAD TO-220
5 LEAD TO-252
AMS1505CM
AMS1505CM-1.5
AMS1505CM-2.5
AMS1505CM-2.85
AMS1505CM-3.0
AMS1505CM-3.3
AMS1505CM-3.5
AMS1505CM-5.0
AMS1505CT
AMS1505CT-1.5
AMS1505CT-2.5
AMS1505CT-2.85
AMS1505CT-3.0
AMS1505CT-3.3
AMS1505CT-3.5
AMS1505CT-5.0
AMS1505CD
AMS1505CD-1.5
AMS1505CD-2.5
AMS1505CD-2.85
AMS1505CD-3.0
AMS1505CD-3.3
AMS1505CD-3.5
AMS1505CD-5.0
Outline Drawing Patterns
Package dimensions are inches (millimeters) unless otherwise noted.
5 Lead TO-263 Plastic Package (M)
0.390-0.415
(9.906-10.541)
0.165-0.180
(4.191-4.572)
0.060
(1.524) TYP
0.004 +0.008
-0.004
(0.102 +0.203 )
-0.102
0.330-0.370
(8.382-9.398)
0.108
(2.74)
TYP
0.199-0.218
(5.05-5.54)
0.057-0.077
(1.447-1.955)
0.045-0.055
(1.143-1.397)
0.032
(0.81)
TYP
0.013-0.023
(0.330-0.584)
0.095-0.115
(2.413-2.921)
0.90-0.110
(2.29-2.79)
M (DD5) AMS DRW#042192R1
5 Lead TO-220 Plastic Package (T)
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AMS1505
Package dimensions are inches (millimeters) unless otherwise noted (continued).
5 Lead TO-252 Plastic Package
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