TSC TS1581CM5

TS1581
5A Dual Input Low Dropout Positive Voltage Regulator
Pin Assignment:
1. Sense
2. Adj / Gnd
3. Output
4. V control
5. V power
Low Dropout Voltage 0.7V max.
Fix or Adjustable Output
General Description
The TS1581 family is a positive adjustable and fixed voltage regulator developed to provide 5A with Higher efficiency than
currently available devices. All internal circuit is designed to operate down to 700mV input to output differential and the
dropout voltage is fully specified as a function of load current. Dropout voltage of the device is 100mV at light loads and
rising to 700mV at maximum output current. A Second low current input is required to achieve this dropout. The TS1581
series are designed to prevent device failure under the worst operation condition with both Thermal Shutdown and
Current Fold-back.
Features
Ordering Information
Very low dropout voltage: 700mV @5A
Part No.
Output current up to 5A
Low current Consumption
Operating Temp.
(Ambient)
TS1581CZ5xx
High Accuracy Output Voltage: +/- 1%
TS1581CZ5
Fast transient response
TO-220-5L
o
0 ~ +85 C
TS1581CM5xx
Remote sense
TO-263-5L
TS1581CM5
Note: Where xx denotes voltage option, available are
3.3V and 2.5V. Leave blank for adjustable version.
Contact factory for additional voltage options.
Internal current limit
Thermal shutdown protection
Applications
Typical Application Circuit
High efficiency linear voltage regulators
Post regulators for switching supplies.
Advance graphic card
Adjustable power supply
Block Diagram
TS1581 series
Package
1-1
2003/12 rev. B
Absolute Maximum Rating
Input Supply Voltage
V power
Vpower
7
V control
Vcontrol
13
PD
Internally Limited
Power Dissipation
Operating Junction Temperature Range
TJ
Storage Temperature Range
TSTG
V
W
0 ~ +125
o
C
-65 ~ +150
o
C
o
Lead Soldering Temperature (260 C)
TO-220-5L / TO-263-5L Package
10
S
Electrical Characteristics
Tj=+25°C, Ccontrol=Cpower=Cout=10uF unless Specified
Parameter
Reference Voltage
(Adj. Voltage Versions)
Output Voltage
(Fixed Voltage Versions)
Line Regulation
Load Regulation
Mini. Load Current (Note 2)
Control Pin Current (Note 3)
Adjust Pin Current
Current Limit
Ripple Rejection
Conditions
Min
VCONTROL = 4.5V, VPOWER = 2.05V, IO = 10mA
1.238
VCONTROL = 4.5V, VPOWER = 2.05V,
1.230
Typ
Max
Unit
1.262
1.250
1.270
V
IO = 10mA to 5A
VCONTROL = 5V, VPOWER =VOUT+0.8V,IO=10mA
-1.0
VCONTROL = 5V, VPOWER = VOUT+0.8V,
-1.6
+1.0
VOUT
IO = 10mA to 5A
VCONTROL = (Vout+1.5V) to 12V,
+1.6
0.04
0.2
0.08
0.4
5
10
mA
80
135
mA
50
120
uA
VPOWER = (VOUT+0.8V) to 5.5V, IO = 10mA
VCONTROL = (Vout+2.5V),
VPOWER = (VOUT+0.8V), IO = 10mA to 5A
VCONTROL=5V, VPOWER= 3.3V, VADJ=0V
VCONTROL = (VOUT+2.5V),
VPOWER = (VOUT+0.8V), IO = 10mA to 5A
VCONTROL = 2.75V, VPOWER = 2.05, VADJ = 0V,
IO = 10mA
VPOWER - VOUT = 3V
VCONTROL = VPOWER = 5V, VRIPPLE = 1V,
IO = 2.5A, f = 120kHz
%
%
%
5.5
6.8
A
60
80
dB
%/W
Thermal Regulation
30mS pulse
0.003
Dropout Voltage (Note 4)
VCONTROL = (Vout+2.5V), IO = 5A
0.55
0.70
V
Note1: VOUT = VSENSE, VADJ = 0V unless otherwise specified.
Note2: 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.
Note3: 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
Note4: If the same voltage is input to both VPOWER and VCONTROL, then the dropout voltage will become 1.3V maximum,
and minimum input/output voltage required to maintain 1% regulation.
TS1581 series
2-2
2003/12 rev. B
Thermal Performance
Condition
Package type
Typ
Thermal Resistance
TO-220-5L
50
Junction to Ambient
TO-263-5L
60
Unit
o
C/W
Pin Description
Pin No.
Pin Name
Pin Description
1
Sense
This pin is the positive side of the reference voltage for this device. With this pin it is
possible to Kelvin Sense the output voltage at the load.
2
Adjust / Ground
This pin is the negative side of the reference voltage for this device. Transient
response can be improved by adding a small bypass capacitor from the adjust pin to
ground.
3
Output
This pin is power output of the device.
4
Control
This pin is the supply pin for the control circuitry for the device. The current flow into
this pin will be about 1% of the output current. For the device to regulate, the voltage
at this pin must be 1.3V greater than the output voltage.
5
Power
This pin is the collector of the power transistor. The output load current is supplied
through this pin. The voltage at this pin must be 0.7V greater than the output voltage
for the device to regulate.
TS1581 series
3-3
2003/12 rev. B
Application Information
Application
Grounding and Output Sensing
The TS1581 is a low dropout regulator designed to
make used of multiple power supplies, present 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 output
transistor to be driven into saturation. For the control
voltage the current requirement is small equal to about
1% of the output current or approximately 50mA for a
5A load. This drive current becomes part of the output
current. The maximum voltage on the Control Pin is
15V. The maximum voltage at the Power in is 7V.By
tying the control and power inputs together the TS1581
can also be operated as a single supply device. In
single supply operation the dropout will be determined
by the minimum control voltage.
Both the fixed and adjustable versions have remote
sense pins, permitting very accurate regulation of
output voltage. As a result, over and output current
range of 100mA to 5A, 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 0.1uF to 1uF for bypassing the
adjust pin.
The new generation of microprocessors cycle load
current from several hundred million amperes to
several amperes in tens of nanoseconds. Output
voltage tolerances are tighter and include transient
response as part of the specification. Designed to meet
the fast current load step requirements of these
microprocessors, the TS1581 also saves total cost by
needing less output capacitance to maintain regulation.
Typical applications for the TS1581 include 3.3V to
2.5V conversion with a 5V control supply, 5V to 4.2V
conversion with a 12V control supply or 5V to 3.6V
conversion with a 12V control supply. It is easy to
obtain dropout voltages less than 0.5V at 1.5A along
with excellent static and dynamic specifications. It is
fully protected against over current and over
temperature conditions.
The TS1581 allows true Kelvin sensing for both the
high & low side of the load. A result the voltage
regulation at the load can be easily optimized. Voltage
drops due to parasitic resistances between the
regulator and the load can be placed inside the
regulation loop. The advantages of remote sensing are
illustrated in Figure 1 through 3.
Figure 1 show 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. Trace A of Figure 3 illustrates the effect of Rp
TS1581 series
4-4
Figure 1. Conventional Load Sensing
Figure 2 show 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.
Figure 2. Remote Load Sensing
2003/12 rev. B
Application Information (continued)
The effect on output regulation can be seen in trace B
of Figure 3. It is important to note that the voltage drops
due to Rp are not eliminated; they will add to the
dropout voltage of the regulator regardless. The
TS1581 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 Rp
Figure 3. Remote Sensing Improves Load Regulation
Because they contain parasitic resistance and
inductance, capacitors are not ideal elements. These
parasitic elements dominate the change in output
voltage as the beginning of a transient load step
change. The ESR of the output capacitors produces
and instantaneous step in output voltage
∆V = ∆I (ESR). The ESL of the output capacitors
produces a drop 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 there transient effects.
Stability
The circuit design used in the TS1581 Series requires
the use of an output capacitor as part of the device
frequency compensation. The addition of 150uF
aluminum electrolytic or a 22uF solid tantalum on the
output will ensure stability for all operating conditions.
In order to meet the transient performance of the
processor larger value capacitors are needed. To limit
the high frequency noise generated by the processor
high quality bypass capacitors must be used. In order
to limit parasitic inductance (ESL) and resistance
(ESR) in capacitors to acceptable limits, multiple small
ceramic capacitors in addition to high quality solid
tantalum capacitors are required.
When the adjustment terminal is bypass 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
further improve stability and transient response of
these devices larger values of output capacitor can be
used. The modern processors 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.
TS1581 series
5-5
Output voltage
The TS1581 (adjustable version) develops a 1.25V
reference voltage between the Sense Pin and the
Adjust Pin (Figure 5). Placing a resistor between these
two terminals causes a constant current to flow though
R1 and down though R2 to set the 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 50uA and it adds
to the current from R1.For best regulation the top of the
resistor divider should be connected directly to the
Sense pin.
Figure 5. Setting Output Voltage
2003/12 rev. B
Application Information (continued)
Protection Diodes
In normal operation TS1581 family does not need any
protection diodes between the Adjust pin and the
output and from the output to the input to prevent die
overstress. Internal resistors are limiting the internal
current paths on the Adjust 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 driver on a transient
basis +/-7V with respect to the output without any
device degradation.
A protection diode between the Output pin and Vpower
pin is not usually needed. Microsecond surge currents
of 50A to 100A 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. Only with high value output capacitors,
such as 1000uF to 5000uF and the Vpower pin is
instantaneously shorted to ground, damage can occur.
A diode from output to input is recommended.
Figure 6. Optional Clamp Diodes Protect Against Input
Crowbar Circuits
If TS1581 is connected as a single supply device with
the control and power input ins shorted together the
internal diode between the output and the power input
pin will protect the control input pin.
Thermal Considerations
The TS1581 family have internal power and thermal
limiting circuit 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,
TS1581 series
6-6
including junction-to-case, case-to-heat sink interface
and heat sink resistance itself. Junction temperature of
o
the Control section can urn up to125 C. Junction
o
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
o
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
o
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 control circuit.
The power in the control circuit is negligible.
The power in the control circuit is equal to:
Pcontrol = ( Vcontrol – Vout ) ( Icontrol )
Where Icontrol is equal Iout / 100 (typ)
The power in the out transistor is equal to:
Poutput = ( Vpower – Vout ) ( Iout )
The total power is equal to:
Ptotal = Pcontrol + Poutput
Junction-to-case thermal resistances 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
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.
2003/12 rev. B
TO-220-5L Mechanical Drawing
G
B
A
H
C
DIM
M
N
L
I
F
K
E
TO-220-5L DIMENSION
MILLIMETERS
INCHES
A
B
C
D
E
F
G
H
I
MIN
10.00
3.240
2.440
0.260
1.570
13.31
4.475
1.170
27.60
MAX
10.50
4.440
2.940
1.020
1.830
14.13
5.225
1.370
29.44
MIN
0.394
0.128
0.096
0.010
0.062
0.524
0.176
0.046
1.087
MAX
0.413
0.175
0.116
0.040
0.072
0.556
0.206
0.054
1.159
J
K
L
M
N
2.175
0.297
8.280
6.010
14.29
2.925
0.477
8.800
6.510
15.31
0.086
0.012
0.326
0.237
0.563
0.115
0.019
0.346
0.256
0.603
J
D
TO-263 Mechanical Drawing
A
E
F
J
B
I
C
G
D
TS1581 series
H
7-7
DIM
A
B
C
D
E
F
G
H
I
J
TO-263-5L DIMENSION
MILLIMETERS
INCHES
MIN
MAX
MIN
MAX
10.220
10.260
0.402
0.404
14.600
15.870
0.575
0.625
0.750
0.770
0.030
0.030
1.573
1.827
0.062
0.072
4.560
4.570
0.179
0.180
1.240
1.270
0.049
0.050
2.280
2.790
0.090
0.110
0.280
0.320
0.011
0.013
8.240
8.280
0.324
0.326
1.540
1.800
0.060
0.071
2003/12 rev. B