Datasheet TC1015-5.0VCT, TC1015-3.3VCT, TC1015-2.7VCT, TC1015-3.0VCT, TC1015-2.5VCT Datasheet (TelCom Semiconductor)

TC1014

1

PRELIMINARY INFORMATION

TC1014-01-6/5/97

50mA CMOS LDO WITH SHUTDOWN
AND REFERENCE BYPASS

TC1014

FEATURES

■ Zero Ground Current for Longer Battery Life!

■ Very Low Dropout Voltage

■ Guaranteed 50mA Output

■ High Output Voltage Accuracy

■ Standard or Custom Output Voltages

■ Power-Saving Shutdown Mode

■ Reference Bypass Input for Ultra Low-Noise

Operation

■ Over-Current and Over-Temperature Protection

■ Space-Saving SOT-23A-5 Package

■ Pin Compatible Upgrade for MIC5205 and

NSC2980

APPLICATIONS

■ Battery Operated Systems

■ Portable Computers

■ Medical Instruments

■ Instrumentation

■ Cellular / GSM / PHS Phones

■ Linear Post-Regulator for SMPS

■ Pagers

50mA CMOS LDO WITH SHUTDOWN AND REFERENCE BYPASS

TYPICAL APPLICATION

TelCom Semiconductor reserves the right to make changes in the circuitry and specifications to its devices.

GENERAL DESCRIPTION

The TC1014 is a high accuracy (typically ±0.5%) CMOS
upgrade for older (bipolar) low dropout regulators such as
the LP2980. Designed specifically for battery-operated sys­tems, the TC1014’s CMOS construction eliminates wasted
ground current, significantly extending battery life. Total
supply current is typically 50µA at full load (

20 to 60 times

lower than in bipolar regulators

!).

TC1014 key features include ultra low-noise operation
(plus optional Bypass input); very low dropout voltage
(typically 95mV at full load) and internal feed-forward com­pensation for fast response to step changes in load. Supply
current is reduced to less than 1µA when the shutdown input
is low. The TC1014 also incorporates both over-tempera­ture and over-current protection.

The TC1014 is stable with an output capacitor of only
1µF and has a maximum output current of 100mA. For
higher output versions, please see the TC1107, TC1108,
TC1173 (I

OUT

= 300mA) data sheets.

1µF

470pF
Reference
Bypass Cap
(Optional)

Shutdown Control

(from Power Control Logic)

TC1014

V

IN

1

2

34

5

V

IN

V

OUT

Bypass

SHDN

GND

V

OUT

PIN CONFIGURATION

ORDERING INFORMATION

Output Junction

Part No. Voltage **(V) Package Temp. Range

TC1014-2.5VCT 2.5 SOT-23A-5* – 40°C to +125°C
TC1014-2.7VCT 2.7 SOT-23A-5* – 40°C to +125°C
TC1014-3.0VCT 3.0 SOT-23A-5* – 40°C to +125°C
TC1014-3.3VCT 3.3 SOT-23A-5* – 40°C to +125°C
TC1014-5.0VCT 5.0 SOT-23A-5* – 40°C to +125°C

NOTE: *SOT-23A-5 is equivalent to the EIAJ (SC-74A)
** Other output voltages available. Please contact TelCom

Semiconductor for details

NOTE: *SOT-23A-5 is equivalent to the EIAJ (SC-74A)

TC1014

(SOT-23A-5*)

1

3

4

5

2

SHDN

Bypass

GND

V

OUT

V

IN

TOP VIEW

TC1014

2

50mA CMOS LDO WITH SHUTDOWN

AND REFERENCE BYPASS

PRELIMINARY INFORMATION

TC1014-01-6/5/97

ABSOLUTE MAXIMUM RATINGS*

Input Voltage .................................................................7V

Output Voltage .................................. (– 0.3) to (VIN + 0.3)

Power Dissipation ....................Internally Limited (Note 7)

Operating Temperature.................... – 40°C < TJ < 125°C

Storage Temperature ............................– 65°C to +150°C

Maximum Voltage On Any Pin .......... VIN + 0.3V to – 0.3V

*Stresses beyond those listed under "Absolute Maximum Ratings" may
cause permanent damage to the device. These are stress ratings only, and
functional operation of the device at these or any other conditions beyond
those indicated in the operational sections of the specifications is not
implied. Exposure to absolute maximum rating conditions for extended
periods may affect device reliability.

ELECTRICAL CHARACTERISTICS:

V

IN

= V

OUT

+ 1V, IL = 100µA, CL = 3.3µF, SHDN > VIH, T

A

= 25°C, unless otherwise noted.

Boldface type specifications apply for junction temperatures of – 40°C to +125°C.

Symbol Parameter Test Conditions Min Typ Max Units

V

IN

Input Operating Voltage — — 6.5 V

I

OUT

MAX

Maximum Output Current 50 —— mA

V

OUT

Output Voltage Note 1 VR – 2.5% VR ±0.5% VR + 2.5% V

TCV

OUT

V

OUT

Temperature Coefficient Note 2 20 — ppm/°C

40

∆V

OUT

/∆V

IN

Line Regulation (VR + 1V) < VIN < 6V — 0.01 — %

∆V

OUT/VOUT

Load Regulation IL = 1.0mA to I

OUT

MAX

— 0.5 — %

(Note 3)

V

IN

– V

OUT

Dropout Voltage (Note 4) IL = 100µA—5—mV

I

L

= 20mA 65

I

L

= 50mA 95

(Note 4)

I

GND

Ground Pin Current IL = I

OUT

MAX,

(Note 5)

—— 0 µA
IINSupply Current SHDN = VIH, IL = 0 — 50 — µA
I

INSD

Shutdown Supply Current SHDN = 0V — — 0.05 µA

PSRR Power Supply Rejection Ratio F

RE

≤ 1kHz — 64 — dB

I

OUT

SC

Output Short Circuit Current V

OUT

= 0V — 200 400 mA

∆V

OUT

/∆P

D

Thermal Regulation Note 6 — 0.04 — %/W

eN Output Noise IL = I

OUT

MAX

— 260 — nV/√Hz

470pF from Bypass to GND

SHDN Input

V

IH

SHDN Input High Threshold VIN = 2.5V to 6.5V 45 — — %V

IN

V

IL

SHDN Input Low Threshold VIN = 2.5V to 6.5V — — 15 %V

IN

NOTES: 1. VR is the regulator output voltage setting. VR = 2.5V, 2.7V, 3.0V, 3.3V, 5.0V.

2. TCV

OUT

= (V

OUT

MAX –

V

OUT

MIN)

x 10

6

V

OUT

x

∆T

3. Regulation is measured at a constant junction temperature using low duty cycle pulse testing. Load regulation is tested over a load
range from 1.0mA to the maximum specified output current. Changes in output voltage due to heating effects are covered by the
thermal regulation specification.

4. Dropout voltage is defined as the input to output differential at which the output voltage drops 2% below its nominal value at a 1V
differential.

5. Ground pin current is the regulator pass transistor gate current. The total current drawn from the input supply is the sum of the load
current, ground current and supply current (i.e. IIN = I

SUPPLY

+ I

GND

+ I

LOAD

).

6. Thermal Regulation is defined as the change in output voltage at a time T after a change in power dissipation is applied, excluding load
or line regulation effects. Specifications are for a current pulse equal to I

LMAX

at VIN = 6V for T = 10msec.

7. The maximum allowable power dissipation is a function of ambient temperature, the maximum allowable junction temperature and the
thermal resistance from junction-to-air (i.e. TA, TJ, θJA). Exceeding the maximum allowable power dissipation causes the device to
initiate thermal shutdown. Please see

Thermal Considerations

section of this data sheet for more details.

.

TC1014

3

PRELIMINARY INFORMATION

TC1014-01-6/5/97

50mA CMOS LDO WITH SHUTDOWN
AND REFERENCE BYPASS

Pin No.

1VINUnregulated supply input.
2 GND Ground terminal.
3 SHDN Shutdown control input. The regulator is fully enabled when a logic high is applied to this

input. The regulator enters shutdown when a logic low is applied to this input. During
shutdown, output voltage falls to zero, and supply current is reduced to under 1 microamp

(typical).
4 Bypass Reference bypass input. Connecting a 470pF to this input further reduces output noise.
5V

OUT

Regulated voltage output.

PIN DESCRIPTION

(SOT-23A-5) Symbol Description

DETAILED DESCRIPTION

The TC1014 is a precision fixed output voltage regula­tor. (If an adjustable version is desired, please see the
TC1070 or TC1071 data sheets.) Unlike the bipolar regula­tors, the TC1014 supply current does not increase with load
current. In addition, V

OUT

remains stable and within regula­tion at very low load currents (an important consideration in
RTC and CMOS RAM battery back-up applications).

Figure 1 shows a typical application circuit. The regula­tor is enabled any time the shutdown input (SHDN) is at or
above VIH, and shutdown (disabled) when SHDN is at or
below VIL. SHDN may be controlled by a CMOS logic gate,
or I/O port of a microcontroller. If the SHDN input is not
required, it should be connected directly to the input supply.
While in shutdown, supply current decreases to 0.05µA
(typical) and V

OUT

falls to zero volts.

Bypass Input

A 470pF capacitor connected from the Bypass input to
ground reduces noise present on the internal reference,
which in turn significantly reduces output noise. If output

noise is not a concern, this input may be left unconnected.
Larger capacitor values may be used, but results in a longer
time period to rated output voltage when power is initially
applied.

Output Capacitor

A 1µF (min) capacitor from V

OUT

to ground is recom­mended. The output capacitor should have an effective
series resistance of 5Ω or less, and a resonant frequency
above 1MHz. A 1µF capacitor should be connected from V

IN

to GND if there is more than 10 inches of wire between the
regulator and the AC filter capacitor, or if a battery is used as
the power source. Aluminum electrolytic or tantalum capaci­tor types can be used. (Since many aluminum electrolytic
capacitors freeze at approximately – 30°C, solid tantalums
are recommended for applications operating below – 25°C.)
When operating from sources other than batteries, supply­noise rejection and transient response can be improved by
increasing the value of the input and output capacitors and
employing passive filtering techniques.

Thermal Considerations

Thermal Shutdown

Integrated thermal protection circuitry shuts the regula­tor off when die temperature exceeds 160°C. The regulator
remains off until the die temperature drops to approximately
150°C.

Power Dissipation

The amount of power the regulator dissipates is prima­rily a function of input and output voltage, and output current.
The following equation is used to calculate worst case

actual

power dissipation:

Figure 1. Typical Application Circuit

1µF

470pF
Reference
Bypass Cap
(Optional)

Shutdown Control

(to CMOS Logic or Tie to V

IN

if Unused)

TC1014

V

IN

BATTERY

V

OUT

BypassSHDN

GND

V

OUT

1µF

TC1014

4

50mA CMOS LDO WITH SHUTDOWN

AND REFERENCE BYPASS

PRELIMINARY INFORMATION

TC1014-01-6/5/97

P

D ≈ (VIN

MAX

–

V

OUT

MIN

)

I

LOAD

MAX

Where:

PD= Worst case actual power dissipation

V

IN

MAX

= Maximum voltage on V

IN

V

OUT

MIN

= Minimum regulator output voltage

I

LOAD

MAX

= Maximum output (load) current

Equation 1.

The maximum

allowable

power dissipation (Equation 2)

is a function of the maximum ambient temperature (T

A

MAX

),
the maximum allowable die temperature (125°C) and the
thermal resistance from junction-to-air (θJA). The
SOT-23A-5 package has a θJA of approximately

220°C/Watt

when mounted on a single layer FR4 dielectric copper clad
PC board.

P

D

MAX

=

(T

J

MAX

– T

J

MAX

)

θ

JA

Where all terms are previously defined.

Equation 2.

Equation 1 can be used in conjunction with Equation 2
to ensure regulator thermal operation is within limits. For
example:

Given:

V

IN

MAX

= 3.0V ±5%

V

OUT

MIN

= 2.7V ±0.5V

I

LOAD

= 40mA

T

AMAX

= 55°C

Find: 1. Actual power dissipation

2. Maximum allowable dissipation

Actual power dissipation:

P

D ≈ (VIN

MAX

–

V

OUT

MIN

)

I

LOAD

MAX

= [(3.0 x 1.1) – (2.7 x .995)]40 x 10

–3

= 18.5mW

Maximum allowable power dissipation:

P

D

MAX

= (T

J

MAX

– T

A

MAX

)

θ

JA

= (125 – 55)
220

= 318mW

In this example, the TC1014 dissipates a maximum of
only 60mW; far below the allowable limit of 318mW. In a
similar manner, Equation 1 and Equation 2 can be used to
calculate maximum current and/or input voltage limits. For
example, the maximum allowable VIN is found by sustituting
the maximum allowable power dissipation of 318mW into
Equation 1, from which V

IN

MAX

= 5.9V.

Layout Considerations

The primary path of heat conduction out of the package
is via the package leads. Therefore, layouts having a
ground plane, wide traces at the pads, and wide power
supply bus lines combine to lower θJA and, therefore,
increase the maximum allowable power dissipation limit.

TC1014

5

PRELIMINARY INFORMATION

TC1014-01-6/5/97

50mA CMOS LDO WITH SHUTDOWN
AND REFERENCE BYPASS

Sales Offices

TelCom Semiconductor

1300 Terra Bella Avenue
P.O. Box 7267
Mountain View, CA 94039-7267
TEL: 415-968-9241
FAX: 415-967-1590
E-Mail: liter@c2smtp.telcom-semi.com

Printed in the U.S.A.

TelCom Semiconductor H.K. Ltd.

10 Sam Chuk Street, 6/F
San Po Kong
Kowloon
Hong Kong
TEL: 852-2324-0122
FAX: 852-2354-9957

TelCom Semiconductor

Austin Product Center
9101 Burnet Rd. Suite 214
Austin, TX 78758
TEL: 512-873-7100
FAX: 512-873-8236

SOT-23A-5*

PACKAGE DIMENSIONS

Dimensions: inches (mm)

.071 (1.80)
.059 (1.50)

.122 (3.10)
.098 (2.50)

.020 (0.50)
.012 (0.30)

.037 (0.95)

REFERENCE

.122 (3.10)
.106 (2.70)

.057 (1.45)
.035 (0.90)

.006 (0.15)
.000 (0.00)

.022 (0.55)
.008 (0.20)

10° MAX.

.010 (0.25)
.004 (0.09)

SOT-23A-5

a & b = part number code + temperature range and voltage

TC1014 (V) Code

2.5 A1

2.7 A2

3.0 A3

3.3 A5

5.0 A7

c represents year and quarter code
d represents lot ID number

NOTE: *SOT-23A-5 is equivalent to the EIAJ (SC-74A)

MARKING

TC1015

1

PRELIMINARY INFORMATION

TC1015-01-6/5/97

100mA CMOS LDO WITH SHUTDOWN
AND REFERENCE BYPASS

TC1015

FEATURES

■ Zero Ground Current for Longer Battery Life!

■ Very Low Dropout Voltage

■ Guaranteed 100mA Output

■ High Output Voltage Accuracy

■ Standard or Custom Output Voltages

■ Power-Saving Shutdown Mode

■ Reference Bypass Input for Ultra Low-Noise

Operation

■ Over-Current and Over-Temperature Protection

■ Space-Saving SOT-23A-5 Package

■ Pin Compatible Upgrade for MIC5205 and

NSC2980

APPLICATIONS

■ Battery Operated Systems

■ Portable Computers

■ Medical Instruments

■ Instrumentation

■ Cellular / GSM / PHS Phones

■ Linear Post-Regulator for SMPS

■ Pagers

100mA CMOS LDO WITH SHUTDOWN AND REFERENCE BYPASS

TYPICAL APPLICATION

TelCom Semiconductor reserves the right to make changes in the circuitry and specifications to its devices.

GENERAL DESCRIPTION

The TC1015 is a high accuracy (typically ±0.5%) CMOS
upgrade for older (bipolar) low dropout regulators such as
the LP2980. Designed specifically for battery-operated sys­tems, the TC1015’s CMOS construction eliminates wasted
ground current, significantly extending battery life. Total
supply current is typically 50µA at full load (

20 to 60 times

lower than in bipolar regulators

!).

TC1015 key features include ultra low-noise operation
(plus optional Bypass input); very low dropout voltage (typi­cally 200mV at full load) and internal feed-forward compen­sation for fast response to step changes in load. Supply
current is reduced to 0.05µA and V

OUT

is disabled when the
shutdown input is low. The TC1015 also incorporates both
over-temperature and over-current protection.

The TC1015 is stable with an output capacitor of only
1µF and has a maximum output current of 100mA. For
higher output versions, please see the TC1107, TC1108,
TC1173 (I

OUT

= 300mA) data sheets.

1µF

470pF
Reference
Bypass Cap
(Optional)

Shutdown Control

(from Power Control Logic)

TC1015

V

IN

1

2

34

5

V

IN

V

OUT

Bypass

SHDN

GND

V

OUT

PIN CONFIGURATION

ORDERING INFORMATION

Output Junction

Part No. Voltage **(V) Package Temp. Range

TC1015-2.5VCT 2.5 SOT-23A-5* – 40°C to +125°C
TC1015-2.7VCT 2.7 SOT-23A-5* – 40°C to +125°C
TC1015-3.0VCT 3.0 SOT-23A-5* – 40°C to +125°C
TC1015-3.3VCT 3.3 SOT-23A-5* – 40°C to +125°C
TC1015-5.0VCT 5.0 SOT-23A-5* – 40°C to +125°C

NOTE: *SOT-23A-5 is equivalent to the EIAJ (SC-74A)
** Other output voltages available. Please contact TelCom

Semiconductor for details

NOTE: *SOT-23A-5 is equivalent to the EIAJ (SC-74A)

TC1015

(SOT-23A-5*)

TOP VIEW

1

3

4

5

2

SHDN

Bypass

GND

V

OUT

V

IN

TC1015

2

100mA CMOS LDO WITH SHUTDOWN

AND REFERENCE BYPASS

PRELIMINARY INFORMATION

TC1015-01-6/5/97

ABSOLUTE MAXIMUM RATINGS*

Input Voltage .................................................................7V

Output Voltage .................................. (– 0.3) to (VIN + 0.3)

Power Dissipation ....................Internally Limited (Note 7)

Operating Temperature.................... – 40°C < TJ < 125°C

Storage Temperature ............................– 65°C to +150°C

Maximum Voltage On Any Pin .......... VIN + 0.3V to – 0.3V

*Stresses beyond those listed under "Absolute Maximum Ratings" may
cause permanent damage to the device. These are stress ratings only, and
functional operation of the device at these or any other conditions beyond
those indicated in the operational sections of the specifications is not
implied. Exposure to absolute maximum rating conditions for extended
periods may affect device reliability.

ELECTRICAL CHARACTERISTICS:

V

IN

= V

OUT

+ 1V, IL = 100µA, CL = 3.3µF, SHDN > VIH, T

A

= 25°C, unless otherwise noted.

Boldface type specifications apply for junction temperatures of – 40°C to +125°C.

Symbol Parameter Test Conditions Min Typ Max Units

V

IN

Input Operating Voltage — — 6.5 V

I

OUT

MAX

Maximum Output Current 100 —— mA

V

OUT

Output Voltage Note 1 VR – 2.5% VR ±0.5% VR + 2.5% V

TCV

OUT

V

OUT

Temperature Coefficient Note 2 20 — ppm/°C

40

∆V

OUT

/∆V

IN

Line Regulation (VR + 1V) < VIN < 6V — 0.01 — %

∆V

OUT/VOUT

Load Regulation IL = 1.0mA to I

OUT

MAX

— 0.5 — %

(Note 3)

V

IN

– V

OUT

Dropout Voltage (Note 4) IL = 0.1mA — 20 — mV

I

L

= 20mA 70

I

L

= 50mA 93

I

L

=100mA 112

(Note 4)

I

GND

Ground Pin Current IL = I

OUT

MAX,

(Note 5)

—— 0 µA
IINSupply Current SHDN = VIH, IL = 0 — 50 — µA
I

INSD

Shutdown Supply Current SHDN = 0V — — 0.05 µA

PSRR Power Supply Rejection Ratio F

RE

≤ 1kHz — 64 — dB

I

OUT

SC

Output Short Circuit Current V

OUT

= 0V — 300 500 mA

∆V

OUT

/∆P

D

Thermal Regulation Note 6 — 0.04 — %/W

eN Output Noise IL = I

OUT

MAX

— 260 — nV/√Hz

470pF from Bypass to GND

SHDN Input

V

IH

SHDN Input High Threshold VIN = 2.5V to 6.5V 45 — — %V

IN

V

IL

SHDN Input Low Threshold VIN = 2.5V to 6.5V — — 15 %V

IN

NOTES: 1. VR is the regulator output voltage setting. VR = 2.5V, 2.7V, 3.0V, 3.3V, 5.0V.

2. TCV

OUT

= (V

OUT

MAX –

V

OUT

MIN)

x 10

6

V

OUT

x

∆T

3. Regulation is measured at a constant junction temperature using low duty cycle pulse testing. Load regulation is tested over a load
range from 1.0mA to the maximum specified output current. Changes in output voltage due to heating effects are covered by the
thermal regulation specification.

4. Dropout voltage is defined as the input to output differential at which the output voltage drops 2% below its nominal value at a 1V
differential.

5. Ground pin current is the regulator pass transistor gate current. The total current drawn from the input supply is the sum of the load
current, ground current and supply current (i.e. IIN = I

SUPPLY

+ I

GND

+ I

LOAD

).

6. Thermal Regulation is defined as the change in output voltage at a time T after a change in power dissipation is applied, excluding load
or line regulation effects. Specifications are for a current pulse equal to I

LMAX

at VIN = 6V for T = 10msec.

7. The maximum allowable power dissipation is a function of ambient temperature, the maximum allowable junction temperature and the
thermal resistance from junction-to-air (i.e. TA, TJ, θJA). Exceeding the maximum allowable power dissipation causes the device to
initiate thermal shutdown. Please see

Thermal Considerations

section of this data sheet for more details.

.

TC1015

3

PRELIMINARY INFORMATION

TC1015-01-6/5/97

100mA CMOS LDO WITH SHUTDOWN
AND REFERENCE BYPASS

Pin No.

1VINUnregulated supply input.
2 GND Ground terminal.
3 SHDN Shutdown control input. The regulator is fully enabled when a logic high is applied to this

input. The regulator enters shutdown when a logic low is applied to this input. During
shutdown, output voltage falls to zero, and supply current is reduced to under 1 microamp

(typical).
4 Bypass Reference bypass input. Connecting a 470pF to this input further reduces output noise.
5V

OUT

Regulated voltage output.

PIN DESCRIPTION

(SOT-23A-5) Symbol Description

DETAILED DESCRIPTION

The TC1015 is a precision fixed output voltage regula­tor. (If an adjustable version is desired, please see the
TC1070 or TC1071 data sheets.) Unlike the bipolar regula­tors, the TC1015 supply current does not increase with load
current. In addition, V

OUT

remains stable and within regula­tion at very low load currents (an important consideration in
RTC and CMOS RAM battery back-up applications).

Figure 1 shows a typical application circuit. The regula­tor is enabled any time the shutdown input (SHDN) is at or
above VIH, and shutdown (disabled) when SHDN is at or
below VIL. SHDN may be controlled by a CMOS logic gate,
or I/O port of a microcontroller. If the SHDN input is not
required, it should be connected directly to the input supply.
While in shutdown, supply current decreases to 0.05µA
(typical) and V

OUT

falls to zero volts.

Bypass Input

A 470pF capacitor connected from the Bypass input to
ground reduces noise present on the internal reference,
which in turn significantly reduces output noise. If output

noise is not a concern, this input may be left unconnected.
Larger capacitor values may be used, but results in a longer
time period to rated output voltage when power is initially
applied.

Output Capacitor

A 1µF (min) capacitor from V

OUT

to ground is recom­mended. The output capacitor should have an effective
series resistance of 5Ω or less, and a resonant frequency
above 1MHz. A 1µF capacitor should be connected from V

IN

to GND if there is more than 10 inches of wire between the
regulator and the AC filter capacitor, or if a battery is used as
the power source. Aluminum electrolytic or tantalum capaci­tor types can be used. (Since many aluminum electrolytic
capacitors freeze at approximately – 30°C, solid tantalums
are recommended for applications operating below – 25°C.)
When operating from sources other than batteries, supply­noise rejection and transient response can be improved by
increasing the value of the input and output capacitors and
employing passive filtering techniques.

Thermal Considerations

Thermal Shutdown

Integrated thermal protection circuitry shuts the regula­tor off when die temperature exceeds 160°C. The regulator
remains off until the die temperature drops to approximately
150°C.

Power Dissipation

The amount of power the regulator dissipates is prima­rily a function of input and output voltage, and output current.
The following equation is used to calculate worst case

actual

power dissipation:

Figure 1. Typical Application Circuit

1µF

470pF
Reference
Bypass Cap
(Optional)

Shutdown Control

(to CMOS Logic or Tie to V

IN

if Unused)

TC1015

V

IN

BATTERY

V

OUT

BypassSHDN

GND

V

OUT

1µF

TC1015

4

100mA CMOS LDO WITH SHUTDOWN

AND REFERENCE BYPASS

PRELIMINARY INFORMATION

TC1015-01-6/5/97

P

D ≈ (VIN

MAX

–

V

OUT

MIN

)

I

LOAD

MAX

Where:

PD= Worst case actual power dissipation

V

IN

MAX

= Maximum voltage on V

IN

V

OUT

MIN

= Minimum regulator output voltage

I

LOAD

MAX

= Maximum output (load) current

Equation 1.

The maximum

allowable

power dissipation (Equation 2)

is a function of the maximum ambient temperature (T

A

MAX

),
the maximum allowable die temperature (125°C) and the
thermal resistance from junction-to-air (θJA). The
SOT-23A-5 package has a θJA of approximately

220°C/Watt

when mounted on a single layer FR4 dielectric copper clad
PC board.

P

D

MAX

=

(T

J

MAX

– T

J

MAX

)

θ

JA

Where all terms are previously defined.

Equation 2.

Equation 1 can be used in conjunction with Equation 2
to ensure regulator thermal operation is within limits. For
example:

Given:

V

IN

MAX

= 3.0V ±10%

V

OUT

MIN

= 2.7V ±0.5V

I

LOAD

= 98mA

T

AMAX

= 55°C

Find: 1. Actual power dissipation

2. Maximum allowable dissipation

Actual power dissipation:

P

D ≈ (VIN

MAX

–

V

OUT

MIN

)

I

LOAD

MAX

= [(3.0 x 1.1) – (2.7 x .995)]98 x 10

–3

= 60mW

Maximum allowable power dissipation:

P

D

MAX

= (T

J

MAX

– T

A

MAX

)

θ

JA

= (125 – 55)
220

= 318mW

In this example, the TC1015 dissipates a maximum of
only 60mW; far below the allowable limit of 318mW. In a
similar manner, Equation 1 and Equation 2 can be used to
calculate maximum current and/or input voltage limits. For
example, the maximum allowable VIN is found by sustituting
the maximum allowable power dissipation of 318mW into
Equation 1, from which V

IN

MAX

= 5.9V.

Layout Considerations

The primary path of heat conduction out of the package
is via the package leads. Therefore, layouts having a
ground plane, wide traces at the pads, and wide power
supply bus lines combine to lower θJA and, therefore,
increase the maximum allowable power dissipation limit.

TC1015

5

PRELIMINARY INFORMATION

TC1015-01-6/5/97

100mA CMOS LDO WITH SHUTDOWN
AND REFERENCE BYPASS

Sales Offices

TelCom Semiconductor

1300 Terra Bella Avenue
P.O. Box 7267
Mountain View, CA 94039-7267
TEL: 415-968-9241
FAX: 415-967-1590
E-Mail: liter@c2smtp.telcom-semi.com

Printed in the U.S.A.

TelCom Semiconductor H.K. Ltd.

10 Sam Chuk Street, 6/F
San Po Kong
Kowloon
Hong Kong
TEL: 852-2324-0122
FAX: 852-2354-9957

TelCom Semiconductor

Austin Product Center
9101 Burnet Rd. Suite 214
Austin, TX 78758
TEL: 512-873-7100
FAX: 512-873-8236

SOT-23A-5*

PACKAGE DIMENSIONS

Dimensions: inches (mm)

.071 (1.80)
.059 (1.50)

.122 (3.10)
.098 (2.50)

.020 (0.50)
.012 (0.30)

.037 (0.95)

REFERENCE

.122 (3.10)
.106 (2.70)

.057 (1.45)
.035 (0.90)

.006 (0.15)
.000 (0.00)

.022 (0.55)
.008 (0.20)

10° MAX.

.010 (0.25)
.004 (0.09)

SOT-23A-5

a & b = part number code + temperature range and voltage

TC1015 (V) Code

2.5 B1

2.7 B2

3.0 B3

3.3 B5

5.0 B7

c represents year and quarter code
d represents lot ID number

NOTE: *SOT-23A-5 is equivalent to the EIAJ (SC-74A)

MARKING