TI TPS2201

TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
•
•
•
•
•
•
•
•
•
•
Fully Integrated VCC and Vpp Switching for
Dual-Slot PC Card Interface
Compatible With Controllers From Cirrus,
Intel, and Texas Instruments
Meets PCMCIA Standards
Internal Charge Pump (No External
Capacitors Required) – 12-V Supply Can Be
Disabled Except for Programming
Short Circuit and Thermal Protection
Space Saving SSOP (DB) Package
Compatible With 3.3-V, 5-V and 12-V PC
Cards
Power Saving IDD = 83 µA Typ, IQ = 1 µA
Low rDS(on) (160-mΩ VCC Switch)
Break-Before-Make Switching
DB OR DF PACKAGE
(TOP VIEW)
5V
5V
A_VPP_PGM
A_VPP_VCC
A_VCC5
A_VCC3
12V
AVPP
AVCC
AVCC
AVCC
GND
APWR_GOOD
SHDN
3V
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
5V
B_VPP_PGM
B_VPP_VCC
B_VCC5
B_VCC3
VDD
12V
BVPP
BVCC
BVCC
BVCC
BPWR_GOOD
OC
3V
3V
description
The TPS2201 PC Card (PCMCIA) power interface switch provides an integrated power-management solution
for two PC Cards. All of the discrete power MOSFETs, a logic section, current limiting, thermal protection, and
power-good reporting for PC Card control are combined on a single integrated circuit (IC), using Texas
Instruments LinBiCMOS process. The circuit allows the distribution of 3-V, 5-V and/or 12-V card power and
is compatible with most PCMCIA controllers. The current-limiting feature eliminates the need for fuses, which
reduces component count and improves reliability; current-limit reporting can help the user isolate a system fault
to a bad card.
The TPS2201 maximizes battery life by generating its own switch-drive voltage using an internal charge pump.
Therefore, the 12-V supply can be powered down and only brought out of standby when flash memory needs
to be written to or erased. End equipment for the TPS2201 includes notebook computers, desktop computers,
personal digital assistants (PDAs), digital cameras, handiterminals, and bar-code scanners.
typical PC card power distribution application
VDD
Power Supply
12V
5V
3V
12 V
5V
3V
CPU
8
PCMCIA
Controller
TPS2201
AVPP
AVCC
AVCC
SHDN
AVCC
Control Lines
APWR_GOOD
BPWR_GOOD
OC
BVPP
BVCC
BVCC
BVCC
Vpp1
Vpp2
VCC
VCC
PC
Card A
Vpp1
Vpp2
VCC
VCC
PC
Card B
LinBiCMOS is a trademark of Texas Instruments Incorporated.
Copyright  1995, Texas Instruments Incorporated
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of Texas Instruments
standard warranty. Production processing does not necessarily include
testing of all parameters.
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
6–1
TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
AVAILABLE OPTIONS
PACKAGED DEVICES
TJ
SHINK SMALL-OUTLINE
(DB)
SMALL-OUTLINE
(DF)
CHIP FORM
(Y)
– 40°C to 150°C
TPS2201IDB
TPS2201IDF
TPS2201Y
† The DF package is only available left-end taped and reeled (indicated by the LE suffix on the device type; e.g.,
TPS2201IDFLE).
Terminal Functions
TERMINAL
NAME
NO.
I/O
DESCRIPTION
A_VCC3
6
I
Logic input that controls voltage on AVCC (see control-logic table)
A_VCC5
5
I
Logic input that controls voltage on AVCC (see control-logic table)
A_VPP_PGM
3
I
Logic input that controls voltage on AVPP (see control-logic table)
A_VPP_VCC
4
I
Logic input that controls voltage on AVPP (see control-logic table)
APWR_GOOD
AVCC
AVPP
13
O
Logic-level power-ready output that stays low as long as AVPP is within limits
9, 10, 11
O
Switched output that delivers 0 V, 3.3 V, 5 V, or high impedance
8
O
Switched output that delivers 0 V, 3.3 V, 5 V, 12 V, or high impedance
B_VCC3
26
I
Logic input that controls voltage on BVCC (see control-logic table)
B_VCC5
27
I
Logic input that controls voltage on BVCC (see control-logic table)
B_VPP_PGM
29
I
Logic input that controls voltage on BVPP (see control-logic table)
B_VPP_VCC
28
I
Logic input that controls voltage on BVPP (see control-logic table)
BPWR_GOOD
19
O
Logic-level power-ready output that stays low as long as BVPP is within limits
BVCC
20, 21, 22
O
Switched output that delivers 0 V, 3.3 V, 5 V, or high impedance
BVPP
23
O
Switched output that delivers 0 V, 3.3 V, 5 V, 12 V, or high impedance
SHDN
14
I
Logic input that shuts down the TPS2201 and set all power outputs to high-impedance state
OC
18
O
Logic-level overcurrent reporting output that goes low when an overcurrent condition exists
VDD
GND
25
5-V power to chip
12
Ground
3V
15, 16, 17
I
3-V VCC input for card power
5V
1, 2, 30
I
5-V VCC input for card power
12V
7, 24
I
12-V VPP input for card power
6–2
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
TPS2201Y chip information
This chip, when properly assembled, displays characteristics similar to the TPS2201. Thermal compression or
ultrasonic bonding may be used on the doped aluminum bonding pads. The chip may be mounted with
conductive epoxy or a gold-silicon preform.
BONDING PAD ASSIGNMENTS
(19)
(14) (13)
(18)
(12)
(16)
(15)
(17)
5V
5V
A_VPP_PGM
A_VPP_VCC
A_VCC5
(20)
(11)
A_VCC3
12V
AVPP
(21)
(10)
AVCC
AVCC
204
AVCC
(22)
(9)
GND
APWR_GOOD
(8)
(23)
SHDN
3V
(24)
(7)
(25)
(6)
(30)
(29)
(3)
(28)
(4)
(27)
(5)
(26)
(6)
(25)
(7)
(24)
(8)
(23)
TPS2201Y
(9)
(22)
(10)
(21)
(11)
(20)
(12)
(19)
(13)
(18)
(14)
(17)
(15)
(16)
5V
B_VPP_PGM
B_VPP_VCC
B_VCC5
B_VCC3
VDD
12V
BVPP
BVCC
BVCC
BVCC
BPWR_GOOD
OC
3V
3V
CHIP THICKNESS: 15 MILS TYPICAL
BONDING PADS: 4 × 4 MILS MINIMUM
(26)
(27)
(1)
(2)
(30) (1)
(28)
(2)
(5)
(3)
(29)
(4)
TJmax = 150°C
TOLERANCES ARE ± 10%
ALL DIMENSIONS ARE IN MILS
142
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
6–3
TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
absolute maximum ratings over operating free-air temperature (unless otherwise noted)†
Supply voltage range, VDD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 0.3 V to 7 V
Input voltage range for card power: VI(5V) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 0.3 V to 7 V
VI(3V) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 0.3 V to VI(5V)
VI(12V) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 0.3 V to 14 V
Logic input voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 0.3 V to 7 V
Continuous total power dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . See Dissipation Rating Table
Output current (each card): IO(xVCC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . internally limited
IO(xVPP) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . internally limited
Operating virtual junction temperature range, TJ . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 40°C to 150°C
Operating free-air temperature range, TA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 40°C to 85°C
Storage temperature range, Tstg . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 55°C to 150°C
Lead temperature 1,6 mm (1/16 inch) from case for 10 seconds . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 260°C
† 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 under “recommended operating conditions” is not
implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
PACKAGE
DB
DISSIPATION RATING TABLE
TA ≤ 25°C
DERATING FACTOR‡
TA = 70°C
POWER RATING
ABOVE TA = 25°C
POWER RATING
1024 mW
8.2 mW/°C
655 mW
TA = 85°C
POWER RATING
532 mW
DF
1158 mW
9.26 mW/°C
741 mW
602 mW
‡ Maximum values are calculated using a derating factor based on RθJA = 108°C/ W for the package.
These devices are mounted on an FR4 board with no special thermal considerations.
recommended operating conditions
Supply voltage, VDD
Input voltage range, VI
Output current
current, IO
MAX
UNIT
5.25
V
VI(5V)
VI(3V)
0
5.25
V
0
V
VI(12V)
IO(xVCC) at 25°C
0
VI(5V)†
13.5
1
IO(xVPP) at 25°C
Operating virtual junction temperature, TJ
† VI(3 V) should not be taken above VI(5 V).
6–4
MIN
4.75
– 40
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
V
A
150
mA
125
°C
TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
electrical characteristics, TA = 25°C, VDD = 5 V (unless otherwise noted)
dc characteristics
PARAMETER
Switch resistances
TPS2201
TEST CONDITIONS
MIN
TYP
MAX
5 V to xVCC
160
3 V to xVCC
225
5 V to xVPP
6
3 V to xVPP
6
12 V to xVPP
mΩ
Ω
1
Clamp low voltage
Ipp at 10 mA
ICC at 10 mA
Clamp low voltage
impedance state
Ipp High
High-impedance
TA = 25°C
TA = 85°C
1
ICC High
High-impedance
impedance state
TA = 25°C
TA = 85°C
1
IDD
VO(AVCC) = VO(BVCC) = 5 V,
VO(AVPP) = VO(BVPP) = 12 V
IDD in shutdown
VO(BVCC) = VO(AVCC) = VO(AVPP)
= VO(BVPP) = high Z
Leakage current
Input current
V
0.8
V
10
10
83
150
µA
1
µA
11.4
V
10.72
11.05
0.75
1.3
1.9
A
120
200
400
mA
50
TJ = 85°C,
85°C
µA
50
Power-ready hysteresis, PWR_GOOD (12-V mode)
IO(xVCC)
IO(xVPP)
0.8
50
Power-ready threshold, PWR_GOOD
Short-circuit outputcurrent limit
UNIT
Output shorted to GND
mV
logic section
PARAMETER
TPS2201
TEST CONDITIONS
MIN
MAX
Logic input current
1
Logic input high level
2.7
0.8
IO = 1 mA
Logic output low level
µA
V
Logic input low level
Logic output high level
UNIT
VDD – 0.4
V
V
0.4
V
switching characteristics†
PARAMETER
TPS2201
TEST CONDITIONS
MIN
TYP
tr
Output rise time
VO(xVCC)
VO(xVPP)
1.2
tf
Output fall time
VO(xVCC)
VO(xVPP)
10
tpd
d
Propagation delay (see Figure 1‡)
5
14
VI(
I(x_VPP_PGM)
VPP PGM) to VO(xVPP)
O( VPP)
ton
toff
5.8
ton
toff
5.8
VI(x_VCC3)
(
CC ) to xVCC (3 V)
VI(
I(x_VCC5)
VCC5) to xVCC (5 V)
ton
toff
18
28
4
30
MAX
UNIT
ms
ms
ms
ms
ms
† Refer to Parameter Measurement Information
‡ Rise and fall times are with CL = 100 µF.
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
6–5
TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
electrical characteristics, TA = 25°C, VDD = 5 V (unless otherwise noted) (continued)
dc characteristics
PARAMETER
TPS2201Y
TEST CONDITIONS
Leakage current
Ipp High-impedance state
ICC High-impedance state
Input current
IDD
MIN
TYP
MAX
1
µA
1
VO(AVCC) = VO(BVCC) = 5 V,
VO(AVPP) = VO(BVPP) = 12 V
µA
83
Power-ready threshold, PWR_GOOD
11.05
Power-ready hysteresis, PWR_GOOD (12-V mode)
UNIT
V
50
mV
switching characteristics†
PARAMETER
TPS2201Y
TEST CONDITIONS
MIN
TYP
tr
Output rise time
VO(xVCC)
VO(xVPP)
1.2
tf
Output fall time
VO(xVCC)
VO(xVPP)
10
tpd
d
Propagation delay (see Figure 1‡)
14
VI(
VPP PGM) to VO(xVPP)
O( VPP)
I(x_VPP_PGM)
ton
toff
5.8
ton
toff
5.8
VI(x_VCC3)
(
CC ) to xVCC
VI(
VCC5) to xVCC
I(x_VCC5)
ton
toff
† Refer to Parameter Measurement Information
‡ Rise and fall times are with CL = 100 µF.
6–6
5
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
18
28
4
30
MAX
UNIT
ms
ms
ms
ms
ms
TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
PARAMETER MEASUREMENT INFORMATION
Vpp
VCC
CL
CL
LOAD CIRCUIT
LOAD CIRCUIT
VDD
VX_VPP_PGM
50%
50%
VDD
50%
Vx_VCCx
50%
GND
VO(xVPP)
GND
toff
ton
toff
ton
VI(12V)
90%
10%
VI(5V)
90%
VO(xVCC)
10%
GND
GND
VOLTAGE WAVEFORMS
VOLTAGE WAVEFORMS
Figure 1. Test Circuits and Voltage Waveforms
Table of Timing Diagrams
FIGURE
xVCC Propagation Delay and Rise Times With 1-µF Load, 3-V Switch
2
xVCC Propagation Delay and Fall Times With 1-µF Load, 3-V Switch
3
xVCC Propagation Delay and Rise Times With 100-µF Load, 3-V Switch
4
xVCC Propagation Delay and Fall Times With 100-µF Load, 3-V Switch
5
xVCC Propagation Delay and Rise Times With 1-µF Load, 5-V Switch
6
xVCC Propagation Delay and Fall Times With 1-µF Load, 5-V Switch
7
xVCC Propagation Delay and Rise Times With 100-µF Load, 5-V Switch
8
xVCC Propagation Delay and Fall Times With 100-µF Load, 5-V Switch
9
xVPP Propagation Delay and Rise Times With 1-µF Load, 12-V Switch
10
xVPP Propagation Delay and Fall Times With 1-µF Load, 12-V Switch
11
xVPP Propagation Delay and Rise Times With 100-µF Load, 12-V Switch
12
xVPP Propagation Delay and Fall Times With 100-µF Load, 12-V Switch
13
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
6–7
TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
PARAMETER MEASUREMENT INFORMATION
x_VCC3 (2 V/div)
x_VCC3 (2 V/div)
xVCC (1 V/div)
0
1
2
xVCC (1 V/div)
3
4
5
6
7
8
9
0
5
10
15
20
25
30
35
40
t – Time – ms
t – Time – ms
Figure 2. xVCC Propagation Delay and
Rise Times With 1-µF Load, 3-V Switch
Figure 3. xVCC Propagation Delay and
Fall Times With 1-µF Load, 3-V Switch
45
x_VCC_3 (2 V/ div)
x_VCC_3 (2 V/div)
xVCC (1 V/div)
xVCC (1 V/div)
0
1
2
3
4
5
6
7
8
9
0
t – Time – ms
10
15
20
25
30
35
40
45
t – Time – ms
Figure 4. xVCC Propagation Delay and
Rise Times With 100-µF Load, 3-V Switch
6–8
5
POST OFFICE BOX 655303
Figure 5. xVCC Propagation Delay and
Fall Times With 100-µF Load, 3-V Switch
• DALLAS, TEXAS 75265
TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
PARAMETER MEASUREMENT INFORMATION
x_VCC_5 (2 V/div)
x_VCC_5 (2 V/div)
xVCC (1 V/div)
0
xVCC (1 V/div)
1
2
3
4
0
5
10
t – Time – ms
15
20
25
30
35
40
45
t – Time – ms
Figure 6. xVCC Propagation Delay and
Rise Times With 1-µF Load, 5-V Switch
Figure 7. xVCC Propagation Delay and
Fall Times With 1-µF Load, 5-V Switch
x_VCC_5 (2 V/div)
xVCC (1 V/div)
x_VCC_5 (2 V/div)
xVCC (1 V/div)
0
1
2
3
4
5
6
7
8
9
0
5
10
15
20
25
30
35
40
45
t – Time – ms
t – Time – ms
Figure 8. xVCC Propagation Delay and
Rise Times With 100-µF Load, 5-V Switch
POST OFFICE BOX 655303
Figure 9. xVCC Propagation Delay and
Fall Times With 100-µF Load, 5-V Switch
• DALLAS, TEXAS 75265
6–9
TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
PARAMETER MEASUREMENT INFORMATION
x_VPP_PGM (2 V/div)
x_VPP_PGM (2 V/div)
xVPP (5 V/div)
xVPP (5 V/div)
0
0.2
0.4 0.6
0.8
1.0
1.2
1.4
1.6
1.8
0
1
2
t – Time – ms
3
4
5
6
7
8
9
t – Time – ms
Figure 10. xVPP Propagation Delay and
Rise Times With 1-µF Load, 12-V Switch
Figure 11. xVPP Propagation Delay and
Fall Times With 1-µF Load, 12-V Switch
x_VPP_PGM (2 V/div)
x_VPP_PGM (2 V/div)
xVPP (5 V/div)
xVPP (5 V/div)
0
1
2
3
4
5
6
7
8
9
0
5
t – Time – ms
15
20
25
30
35
40
45
t – Time – ms
Figure 12. xVPP Propagation Delay and
Rise Times With 100-µF Load, 12-V Switch
6–10
10
POST OFFICE BOX 655303
Figure 13. xVPP Propagation Delay and
Fall Times With 100-µF Load, 12-V Switch
• DALLAS, TEXAS 75265
TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
TYPICAL CHARACTERISTICS†
Table of Graphs
FIGURE
IDD
rDS(on)
Supply current
vs Junction temperature
14
Static drain-source on-state resistance, 3-V switch
vs Junction temperature
15
rDS(on)
Static drain-source on-state resistance, 5-V switch
vs Junction temperature
16
rDS(on)
Static drain-source on-state resistance, 12-V switch
vs Junction temperature
17
VO(xVCC)
VO(xVCC)
Output voltage, 5-V switch
vs Output current
18
Output voltage, 3-V switch
vs Output current
19
xVpp
Output voltage, Vpp switch
vs Output current
20
ISC(xVCC)
ISC(xVPP)
Short-circuit current, 5-V switch
vs Junction temperature
21
Short-circuit current, 12-V switch
vs Junction temperature
22
SUPPLY CURRENT
vs
JUNCTION TEMPERATURE
100
VO(AVCC) = VO(BVCC) = 5 V
VO(AVPP) = VO(BVPP) = 12 V
No load
I DD – Supply Current – µ A
95
ÁÁ
ÁÁ
ÁÁ
90
85
80
75
– 50
50
0
100
150
TJ – Junction Temperature – °C
Figure 14
† t = pulse tested
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
6–11
TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
3-V SWITCH
5-V SWITCH
STATIC DRAIN-SOURCE ON-STATE RESISTANCE
vs
JUNCTION TEMPERATURE
STATIC DRAIN-SOURCE ON-STATE RESISTANCE
vs
JUNCTION TEMPERATURE
400
350
VDD = 5 V
VCC = 3.3 V
300
250
200
150
100
50
0
– 50
– 25
0
25
50
75
100
TJ – Junction Temperature – °C
125
r DS(on) – Static Drain-Source On-State Resistance – m Ω
r DS(on) – Static Drain-Source On-State Resistance – m Ω
TYPICAL CHARACTERISTICS†
240
VDD = 5 V
VCC = 5 V
220
200
180
160
140
120
100
80
– 50
– 25
25
50
75
100
0
TJ – Junction Temperature – °C
Figure 16
12-V SWITCH
5-V SWITCH
STATIC DRAIN-SOURCE ON-STATE RESISTANCE
vs
JUNCTION TEMPERATURE
OUTPUT VOLTAGE
vs
OUTPUT CURRENT
5.05
1700
VDD = 5 V
VCC = 5 V
VDD = 5 V
Vpp = 12 V
5
1500
– 40°C
VO(xVCC) – Output Voltage – V
r DS(on) – Static Drain-Source On-State Resistance – m Ω
Figure 15
1300
1100
900
700
500
– 50
4.99
4.9
25°C
4.85
85°C
125°C
4.8
4.75
– 25
0
25
50
75
100
125
0
0.1
TJ – Junction Temperature – °C
Figure 17
0.6
0.2
0.3
0.4
0.5
IO(xVCC) – Output Current – A
Figure 18
† t = pulse tested
6–12
125
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0.7
TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
TYPICAL CHARACTERISTICS†
3-V SWITCH
Vpp SWITCH
OUTPUT VOLTAGE
vs
OUTPUT CURRENT
OUTPUT VOLTAGE
vs
OUTPUT CURRENT
12.05
3.35
VDD = 5 V
Vpp = 12 V
3.3
12
xVpp – Output Voltage – V
VO(xVCC) – Output Voltage – V
VDD = 5 V
VCC = 3.3 V
– 40°C
3.25
25°C
3.2
3.15
– 40°C
25°C
11.95
11.90
85°C
11.85
3.1
125°C
125°C
85°C
11.80
3.05
0
0.1
0.2
0.3
0.4
0.5
0.6
0
0.7
0.02
0.04
Figure 19
0.08
0.1
0.12
Figure 20
5-V SWITCH
12-V SWITCH
SHORT-CIRCUIT CURRENT
vs
JUNCTION TEMPERATURE
SHORT-CIRCUIT CURRENT
vs
JUNCTION TEMPERATURE
400
2
VDD = 5 V
VCC = 5 V
I SC(xVPP) – Short-Circuit Current – mA
I SC(xVCC) – Short-Circuit Current – A
0.06
IO(xVPP) – Output Current – A
IO(xVCC) – Output Current – A
1.5
1
0.5
– 50
0
50
100
150
VDD = 5 V
Vpp = 12 V
350
300
250
200
150
100
– 50
TJ – Junction Temperature – °C
Figure 21
100
0
50
TJ – Junction Temperature – °C
150
Figure 22
† t = pulse tested
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TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
APPLICATION INFORMATION
overview
PC Cards were initially introduced as a means to add EEPROM (flash memory) to portable computers with
limited on-board memory. The idea of add-in cards quickly took hold: modems, wireless LANs, GPS systems,
multimedia, and hard-disk versions were soon available. As the number of PC Card applications grew, the
engineering community quickly recognized the need for a standard to ensure compatibility across platforms.
To this end, the PCMCIA (Personal Computer Memory Card International Association) was established and was
comprised of members from leading computer, software, PC card, and semiconductor manufacturers. One key
goal was to realize the concept of plug and play – cards and hosts from different vendors should be compatible
and able to communicate with one another transparently.
PC Card power specification
System compatibility also means power compatibility. The most current set of specifications (PC Card Standard)
set forth by the PCMCIA committee states that power is to be transferred between the host and the card through
eight of the PC Card connector’s 68 pins. This power interface consists of two VCC, two Vpp, and four ground
pins. Multiple VCC and ground pins are used to minimize connector-pin and line resistance. The two Vpp pins
were originally specified as separate signals but are commonly tied together in the host to form a single node
to minimize voltage losses. Card primary power is supplied through the VCC pins; flash-memory programming
and erase voltage is supplied through the Vpp pins. As each pin is rated to 0.5 A, VCC and Vpp can theoretically
supply up to 1 A, assuming equal pin resistance and no pin failure. A conservative design would limit current
to 500 mA. Some applications, however, require higher VCC currents; disk drives, for example, may need as
much as 750-mA peak current to create the initial torque necessary to spin up the platter. Vpp currents, on the
other hand, are defined by flash-memory programming requirements, typically under 120 mA.
future power trends
The 1-A physical-pin current alluded to in the PC Card specification has caused some host-system engineers
to believe they are required to deliver 1 A within the voltage tolerance of the card. Future applications, such as
RF cards, could use the extra power for their radio transmitters. The 5 W required for these cards will require
very robust power supplies and special cooling considerations. The limited number of host sockets that will be
able to support them makes the market for these high-powered PC Cards uncertain. The vast majority of the
cards require less than 600 mA continuous current and the trend is towards even lower-powered PC Cards that
will assure compatibility with a greater number of host systems. Recognizing the need for power derating, an
adhoc committee of the PCMCIA is currently working to limit the amount of steady-state dc current to the
PC Card to something less than the currently implied 1 A. If a system is designed to support 1 A, then the switch
rDS(on), power supply requirements, and PC Card cooling need to be carefully considered.
designing around 1-A delivery
Delivering 1 A means minimizing voltage (and power) losses across the PC Card power interface, which
requires that designers trade off switch resistance and the cost associated with large-die (low rDS(on)) MOSFET
transistors. The PC Card standard requires that 5 V ±5%, or 3.3 V ±0.3 V be supplied to the card. The
approximate 10% tolerance for the 3.3-V supply makes the 3.3-V rDS(on) less critical than the 5-V switch. A
conservative approach is to allow 2% for voltage-regulator tolerance and 1% for etch- and terminal-resistance
drops, which leaves 2% (100 mV) voltage drop for the 5-V switch, and at least 6% (198 mV) for the 3.3-V switch.
Calculating the rDS(on) necessary to support a 100 mV or 198 mV switch loss, using R = E/I and setting I = 1 A,
the 5-V and 3.3-V switches would need to be 100 mΩ and 198 mΩ respectively. One solution would be to pay
for a more expensive switch with lower rDS(on). A second, less expensive approach is to increase the headroom
of the power supply–for example, to increase the 5-V supply 1.5% or to 5.075 ±2%. Working through the
numbers once more, the 2% for the regulator plus 1 % for etch and terminal losses leaves 97% or 4.923 V. The
allowable
6–14
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DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
APPLICATION INFORMATION
designing around 1-A delivery (continued)
voltage loss across the power distribution switch is now 4.923 V minus 4.750 V or 173 mV. Therefore, a switch
with 173 mΩ or less could deliver 1 A or greater. Setting the power supply high is a common practice for
delivering voltages to allow for system switch, connector, and etch losses and has a minimal effect on overall
battery life. In the example above, setting the power supply 1.5% high would only decrease a 3-hour battery life
by approximately 2.7 minutes, trivial when compared with the decrease in battery life when running a 5-W PC
Card.
heat dissipation
A greater concern in delivering 1 A or 5 W is the ability of the host to dissipate the heat generated by the PC
Card. For desktop computers the solution is simpler: locate the PC Card cage such that it receives convection
cooling from the forced air of the fan. Notebooks and other handheld equipment will not be able to rely on
convection, but must rely on conduction of heat away from the PC Card through the rails into the card cage. This
is difficult because PC Card/card cage heat transfer is very poor. A typical design scenario would require the
PC Card to be held at 60°C maximum with the host platform operating as high as 50°C. Preliminary testing
reveals that a PC Card can have a 20°C rise, exceeding the 10°C differential in the example, when dissipating
less than 2 W of continuous power. The 60°C temperature was chosen because it is the maximum operating
temperature allowable by PC Card specification. Power handling requirements and temperature rises are topics
of concern and are currently being addressed by the PCMCIA committee.
overcurrent and over-temperature protection
PC Cards are inherently subject to damage that can result from mishandling. Host systems require protection
against short-circuited cards that could lead to power supply or PCB-trace damage. Even systems sufficiently
robust to withstand a short circuit would still undergo rapid battery discharge into the damaged PC Card,
resulting in the rather sudden and unacceptable loss of system power. This can be particularly frustrating to the
consumer who has already experienced problems with shortened battery life due to improper Nicad conditioning
or memory effect. Most hosts include fuses for protection. The reliability of fused systems is poor, though, as
blown fuses require troubleshooting and repair, usually by the manufacturer. The TPS2201 takes a two-pronged
approach to overcurrent protection. First, instead of fuses, sense FETs monitor each of the power outputs.
Excessive current generates an error signal that linearly limits the output current, preventing host damage or
failure. Sense FETs, unlike sense resistors or polyfuses, have the added advantage that they do not add to the
series resistance of the switch and thus produce no additional voltage losses. Second, when an overcurrent
condition is detected, the TPS2201 asserts a signal at OC that can be monitored by the microprocessor to initiate
diagnostics and/or send the user a warning message. In the event that an overcurrent condition persists,
causing the IC to exceed its maximum junction temperature, thermal-protection circuitry engages, shutting
down all power outputs until the device cools to within a safe operating region.
12-V supply not required
Most PC Card switches use the externally supplied 12-V Vpp power for switch-gate drive and other chip
functions, requiring that it be present at all times. The TPS2201 offers considerable power savings by using an
internal charge pump to generate the required higher voltages from the 5-V VDD supply; therefore, the external
12-V supply can be disabled except when needed for flash-memory functions, thereby extending battery
lifetime. Additional power savings are realized by the TPS2201 during a software shutdown, in which quiescent
current drops to a maximum of 1 µA.
voltage transitioning requirement
PC Cards, like portables, are migrating from 5 V to 3.3 V to minimize power consumption, optimize board space,
and increase logic speeds. The TPS2201 is designed to meet all combinations of power delivery as currently
defined in the PCMCIA standard. The latest protocol accommodates mixed 3.3-V/5-V systems by first powering
the card with 5 V, then polling it to determine its 3.3-V compatibility. The PCMCIA specification requires that the
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TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
APPLICATION INFORMATION
voltage transitioning requirement (continued)
capacitors on 3.3-V compatible cards be discharged to below 0.8 V before applying 3.3-V power. This ensures
that sensitive 3.3-V circuitry is not subjected to any residual 5-V charge and functions as a power reset. The
TPS2201 offers a selectable VCC and VPP ground state, per PCMCIA 3.3-V/5-V switching specifications, to fully
discharge the card capacitors while switching between VCC voltages.
output ground switches
Several PCMCIA power-distribution switches on the market do not have an active-grounding FET switch. These
devices do not meet the PC Card specification requiring a discharge of VCC within 100 ms. PC Card resistance
can not be relied on to provide a discharge path for voltages stored on PC Card capacitance because of possible
high-impedance isolation by power-management schemes. A method commonly shown to alleviate this
problem is to add to the switch output an external 100 kΩ resistor in parallel with the PC Card. Considering that
this is the only discharge path to ground, a timing analysis will reveal that the RC time constant delays the
required discharge time to over 2 seconds. The only way to ensure timing compatibility with PC Card standards
is to use a power-distribution switch that has an internal ground switch, like that of the TPS22xx family, or add
an external ground FET to each of the output lines with the control logic necessary to select it.
In summary, the TPS2201 is a complete single-chip dual-slot PC Card power interface. It meets all currently
defined PCMCIA specifications for power delivery in 5-V, 3.3-V, and mixed systems, and offers a serial controller
interface. The TPS2201 offers functionality, power savings, overcurrent and thermal protection, and fault
reporting in one 30-pin SSOP surface-mount package for maximum value added to new portable designs.
power supply considerations
The TPS2201 has multiple terminals for each of its 3.3 V, 5 V, and 12 V power inputs and for the switched VCC
outputs. Any individual terminal can conduct the rated input or output current. Unless all terminals are connected
in parallel, the series resistance is significantly higher than that specified, resulting in increased voltage drops
and lost power. Both 12 V inputs must be connected for proper Vpp switching; it is recommended that all input
and output power terminals be paralleled for optimum operation. The VDD input lead must be connected to the
5V input leads.
Although the TPS2201 is fairly immune to power input fluctuations and noise, it is generally considered good
design practice to bypass power supplies typically with a 1-µF electrolytic or tantalum capacitor paralleled by
a 0.047-µF to 0.1-µF ceramic capacitor. It is strongly recommended that the switched VCC and Vpp outputs be
bypassed with a 0.1-µF or larger capacitor; doing so improves the immunity of the TPS2201 to electrostatic
discharge (ESD). Care should be taken to minimize the inductance of PCB traces between the TPS2201 and
the load. High switching currents can produce large negative-voltage transients, which forward biases substrate
diodes, resulting in unpredictable performance.
The TPS2201, unlike other PC Card power-interface switches, does not use the 12-V power supply for switching
or other chip functions. Instead, an internal charge pump generates the necessary voltage from VDD, allowing
the 12-V input supply to be shut down except when the Vpp programming or erase voltage is needed. Careful
system design making use of this feature reduces power consumption and extends battery lifetime.
The 3.3-V power input should not be taken higher than the 5-V input. Doing so, though nondestructive, results
in high current flow into the device, and could result in abnormal operation. In any case, this occurrence indicates
a malfunction of one input voltage or both, which should be investigated.
Similarly, no terminal should be taken below – 0.3 V; forward biasing the parasitic-substrate diode results in
substrate currents and unpredictable performance.
6–16
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DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
APPLICATION INFORMATION
overcurrent and thermal protection
The TPS2201 uses sense FETs to check for overcurrent conditions in each of the VCC and Vpp outputs. Unlike
sense resistors or polyfuses, these FETs do not add to the series resistance of the switch; therefore, voltage
and power losses are reduced. Overcurrent sensing is applied to each output separately. When an overcurrent
condition is detected, only the power output affected is limited; all other power outputs continue to function
normally. The OC indicator, normally a logic high, is a logic low when any overcurrent condition is detected,
providing for initiation of system diagnostics and/or sending a warning message to the user.
During power up, the TPS2201 controls the rise time of the VCC and Vpp outputs and limits the current into a
faulty card or connector. If a short circuit is applied after power is established (e.g., hot insertion of a bad card),
current is initially limited only by the impedance between the short and the power supply. In extreme cases, as
much as 10 A to 15 A may flow into the short before the current limiting of the TPS2201 engages. If the VCC
or Vpp outputs are driven below ground, the TPS2201 may latch nondestructively in an off state. Cycling power
will reestablish normal operation.
Overcurrent limiting for the VCC outputs is designed to engage if powered up into a short in the range of
0.75 A to 1.9 A, typically at about 1.3 A; the Vpp outputs limit from 120 mA to 400 mA, typically around 200 mA.
The protection circuitry acts by linearly limiting the current passing through the switch, rather than initiating a
full shutdown of the supply. Shutdown occurs only during thermal limiting.
Thermal limiting prevents destruction of the IC from overheating when the package power-dissipation ratings
are exceeded. Thermal limiting, disables all power outputs (both A and B slots) until the device has cooled.
calculating junction temperature
The switch resistance, rDS(on), is dependent on the junction temperature, TJ, of the die. The junction temperature
is dependent on both rDS(on) and the current through the switch. To calculate TJ, first find rDS(on) from Figures
16, 17, and 18 using an initial temperature estimate about 50°C above ambient. Then calculate the power
dissipation for each switch, using the formula:
P
D
+ rDS(on) @ I2
ǒS
Ǔ
Next, sum the power dissipation and calculate the junction temperature:
T
J
+
P
D
@ RqJA ) TA,
R
qJA + 108 °CńW
Compare the calculated junction temperature with the initial temperature estimate. If they are not within a few
degrees of each other, reiterate using the calculated temperature as the initial estimate.
logic input and outputs
The TPS2201 was designed to be compatible with most popular PCMCIA controllers and current PCMCIA and
JEIDA standards. However, some controllers require slightly counterintuitive connections to achieve desired
output states. The TPS2201 control logic inputs A_VCC3, A_VCC5, B_VCC3 and B_VCC5 are defined active
low (see Figure 23 and control-logic table). As such, they are directly compatible with the Cirrus Logic
CL-PD6720 controller’s logic outputs (see Figure 24). The TPS2201 separate Vpp power good indicators can
be ORed together to provide a single input to the Cirrus controller.
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TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
APPLICATION INFORMATION
TPS2201
S7
S9
S2
3V
S3
CS
3V
3V
17
12V
12V
9
10
17
11
51
20
17
21
51
VCC
VCC
Card B
S4
S6
5V
VPP2
CS
CS
5V
VPP1
16
S5
5V
18
52
S8
S1
15
Card A
8
S10
1
S12
30
CS
VCC
22
S11
2
VCC
18
23
52
VPP1
VPP2
7
24
Internal
Current Monitor
CPU
14
SHDN
Logic
Thermal
Controller
3
4
5
6
29
28
27
26
19
13
18
A_VPP_PGM
A_VPP_VCC
A_VCC5
A_VCC3
B_VPP_PGM
B_VPP_VCC
B_VCC5
B_VCC3
D0 – D7
25
VDD
BPWR_GOOD
APWR_GOOD
GND
OC
12
Figure 23. Internal Switching Matrix
6–18
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SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
APPLICATION INFORMATION
TPS2201 control logic
AVPP
CONTROL SIGNALS
INTERNAL SWITCH SETTINGS
SHDN
A_VPP_PGM
A_VPP_VCC
S7
1
0
0
1
0
1
1
1
OUTPUT
S8
S9
VAVPP
CLOSED
OPEN
OPEN
0V
OPEN
CLOSED
OPEN
VCC†
0
OPEN
OPEN
CLOSED
VPP(12 V)
1
1
1
OPEN
OPEN
OPEN
Hi-Z
0
X
X
OPEN
OPEN
OPEN
Hi-Z
BVPP
CONTROL SIGNALS
INTERNAL SWITCH SETTINGS
SHDN
B_VPP_PGM
B_VPP_VCC
S10
1
0
0
1
0
1
1
1
OUTPUT
S11
S12
VBVPP
CLOSED
OPEN
OPEN
0V
OPEN
CLOSED
OPEN
VCC‡
0
OPEN
OPEN
CLOSED
VPP(12 V)
1
1
1
OPEN
OPEN
OPEN
Hi-Z
0
X
X
OPEN
OPEN
OPEN
Hi-Z
AVCC
CONTROL SIGNALS
INTERNAL SWITCH SETTINGS
OUTPUT
SHDN
A_VCC3
A_VCC5
S1
S2
S3
VAVCC
1
0
0
CLOSED
OPEN
OPEN
0V
1
0
1
OPEN
CLOSED
OPEN
3V
1
1
0
OPEN
OPEN
CLOSED
5V
1
1
1
CLOSED
OPEN
OPEN
0V
0
X
X
OPEN
OPEN
OPEN
Hi-Z
BVCC
CONTROL SIGNALS
INTERNAL SWITCH SETTINGS
OUTPUT
SHDN
B_VCC3
B_VCC5
S4
S5
S6
VBVCC
1
0
0
CLOSED
OPEN
OPEN
0V
1
0
1
OPEN
CLOSED
OPEN
3V
1
1
0
OPEN
OPEN
CLOSED
5V
1
1
1
CLOSED
OPEN
OPEN
0V
0
X
X
OPEN
OPEN
OPEN
Hi-Z
† Output depends on AVCC
‡ Output depends on BVCC
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TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
APPLICATION INFORMATION
logic input and outputs (continued)
TPS2201
Cirrus Logic
CL-PD6720
A_Vpp _PGM
A_Vpp_VCC
A_VPP_PGM
A_VPP_VCC
A_VCC_3
A_VCC_5
A_VCC3
A_VCC5
B_VPP_PGM
B_Vpp _PGM
B_Vpp_VCC
B_VPP_VCC
B_VCC3
B_VCC_3
B_VCC_5
B_VCC5
APWR_GOOD
Vpp _Valid
BPWR_GOOD
OC
GND
To CPU
Figure 24. Logic Connections to CL-PD6720
Intel’s 82365SLDF controller uses active-high control logic for VCC selection, which requires connecting the
82365SLDF’s 3-V control outputs (A_VCC_EN0, B_VCCEN0) to the TPS2201’s 5-V control inputs (A_VCC5,
B_VCC5) and the 5-V control outputs (AVCC_EN1, B_VCC_EN1) to the 3-V control inputs (A_VCC3, B_VCC3),
as illustrated in Figure 25. Examination of the control logic tables on page 16 will confirm that these connections
will in fact select the correct output voltage. An alternative approach would be to invert the Intel VCC control logic
signals before routing them to the TPS2201.
The separate Vpp power-good indicators of the TPS2201 can be connected directly to the Intel controller as
shown in Figure 25.
Cirrus Logic defines a (1, 1) on the VCC select lines to be the PC Card no connect state; Intel chose (0, 0) to
select this state. As the tables show, either combination switches the VCC outputs to 0 V. The decision to provide
0 V versus a high impedance for the no connect state eliminates potential charging at the switch-to-card
interface. Feedback from the PC Card design community favors this approach.
Vpp logic allows for 0-V or high-impedance output for no connect (0, 0) or reserved (1, 1) logic inputs, respectively
(refer to AVPP and BVPP control-logic tables on page 16). Both the Cirrus Logic and Intel controllers interface
directly with the Vpp control inputs of the TPS2201.
The shutdown input of the TPS2201, SHDN, when held at a logic low places all VCC and Vpp outputs in a
high-impedance state and reduces chip quiescent current to 1 µA to conserve battery power.
An overcurrent output (OC) is provided to indicate an overcurrent condition in any of the VCC or Vpp supplies
(see discussion above).
ESD protection
All TPS2201 inputs and outputs incorporate ESD-protection circuitry designed to withstand a 2-kV
human-body-model discharge as defined in MIL-STD-883C. The VCC and Vpp outputs can be exposed to
potentially higher discharges from the external environment through the PC card connector. Bypassing the
outputs with 0.1-µF capacitors protects the devices from discharges up to 10 kV.
6–20
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TPS2201, TPS2201Y
DUAL-SLOT PC CARD POWER-INTERFACE SWITCHES
FOR PARALLEL PCMCIA CONTROLLERS
SLVS094B – AUGUST 1994 – REVISED AUGUST 1995
APPLICATION INFORMATION
5V
VDD
AVCC
0.1 µF
AVCC
12 V
12V
AVCC
VCC
VCC
Vpp1
Vpp2
12V
PC Card
Connector A
BVCC
BVCC
BVCC
0.1 µF
TPS2201
Vpp1
Vpp2
AVPP
5V
0.1 µF
AVPP
5V
VCC
VCC
PC Card
Connector B
5V
5V
3V
BVPP
0.1 µF
BVPP
3V
3V
A_VCC5
3V
A_VCC _EN0
A_VCC _EN1
A_VCC3
A_VPP_VCC
A_Vpp _EN0
A_Vpp _EN1
A_VPP_PGM
B_VCC5
B_VCC _EN0
B_VCC _EN1
B_VCC3
B_VPP_VCC
B_Vpp _EN0
B_Vpp _EN1
B_VPP_PGM
APWR_GOOD
A:GPI
BPWR_GOOD
B:GPI
OC
GND
INTEL
82365SL DF
To CPU
SHDN
CS
Shutdown
Signal
From CPU
Figure 25. Detailed Operating Circuits Using Intel 82365SLDF Controller
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6–21
6–22
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IMPORTANT NOTICE
Texas Instruments and its subsidiaries (TI) reserve the right to make changes to their products or to discontinue
any product or service without notice, and advise customers to obtain the latest version of relevant information
to verify, before placing orders, that information being relied on is current and complete. All products are sold
subject to the terms and conditions of sale supplied at the time of order acknowledgement, including those
pertaining to warranty, patent infringement, and limitation of liability.
TI warrants performance of its semiconductor products to the specifications applicable at the time of sale in
accordance with TI’s standard warranty. Testing and other quality control techniques are utilized to the extent
TI deems necessary to support this warranty. Specific testing of all parameters of each device is not necessarily
performed, except those mandated by government requirements.
CERTAIN APPLICATIONS USING SEMICONDUCTOR PRODUCTS MAY INVOLVE POTENTIAL RISKS OF
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