HPC3130APBKG4 - Texas Instruments

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

DCompliant With PCI Hot-Plug Specification,

Revision 1.0

DSupports up to Four Independently

Controlled Hot-Plug Slots

DProvides Register Accessing Through Both

Generic Parallel Bus and Two-Wire Serial

Interface

DProvides Interrupt and Event Status/Enable

State Compliant With ACPI Specification

1.0

DProvides an Automatic Bus Connection

Sequencing Feature

DSupports 66-MHz PCI Clock Frequency

DFeatures Two Attention Indicators With

Variable LED Blinking Rates per Slot

DProvides an Easy Scheme to Cascade the

HPC3130A for Compact PCI Applications

DProvides Card Detection Mechanism

Independent of PCI Present Signals for

Advanced Card Protection

DProvides Path to Guarantee Idle State

During PCI Bus Connections

DFabricated in Advanced Low-Power CMOS

Process

DFeatures a CBT Switch† Control Feature for

REQ64 Implementation

DPackage Options:

– 120-pin QFP Package

– 128-pin LQFP Package

– 144-pin LQFP Package

Table of Contents

Description 2. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 66 MHz PCI Support 24. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Functional Block Diagram 2. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Configuration and Control Registers 25. . . . . . . . . . . . . . . . . . . . . . . . .

Pin Assignments (120-Pin) 3. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Absolute Maximum Ratings 32. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Pin Assignments (128-Pin) 4. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Recommended Operating Conditions 33. . . . . . . . . . . . . . . . . . . . . . . .

Pin Assignments (144-Pin) 5. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Serial Bus Interface 34. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Signal Name/Pin Number Sort Table (120-Pin) 6. . . . . . . . . . . . . . . . . Electrical Characteristics 34. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Signal Name/Pin Number Sort Table (128-Pin) 8. . . . . . . . . . . . . . . . . PCI Clock/Reset Timing Requirements 35. . . . . . . . . . . . . . . . . . . . . . .

Signal Name/Pin Number Sort Table (144-Pin) 10. . . . . . . . . . . . . . . . PCI Timing Requirements 36. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Terminal Functions 12. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Mechanical Data (120-Pin) 37. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

HPC3130A Applications 15. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Mechanical Data (128-Pin) 38. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

64-Bit Implementation 23. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Mechanical Data (144-Pin) 39. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of

Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.

† Contact Texas Instrument’s Bus Interface product group for information related to CBT switches.

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.

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

2POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

description

The Texas Instruments HPC3130A is a peripheral component interconnect (PCI) hot-plug controller, compliant

with

PCI Hot-Plug Specification, Revision 1.0

. This device supports hot insertion/removal of up to four hot-plug

slots on a PCI bus, provides a 64-bit data path in any of the four hot-plug slots, and supports 66-MHz systems

for two slots.

The primary function of the HPC3130A is to allow noninterfering hot-plug slot connection/disconnection with

the other PCI devices on the bus. The HPC3130A provides automatic bus connection sequencing and supports

a protocol for connection during bus idle conditions. It also supports an interrupt pin to report hot-plug slot

events. The interrupt event status and enable state are compliant with the

Advanced Configuration and Power

Interface (ACPI) Specification

Internal registers may be accessed through either a two-signal serial interface or a generic parallel bus. The

serial interface slave decoding circuit supports up to eight different controllers or other serial bus devices with

the same system base. Decoding through the parallel interface supports multiple controllers with external

chip-select logic. Two double-words of configuration and control registers are provided per slot. As a result, the

HPC3130A decodes an address range of 32 bytes.

An advanced complementary metal-oxide semiconductor (CMOS) process provides low system power

consumption while operating at PCI clock rates up to 66 MHz.

functional block diagram

A simplified block diagram of the HPC3130A is provided below. The block diagram illustrates the HPC3130A

functionality on a per slot basis. The SMODE chip input, not shown, is used for terminal multiplexing of the serial

and parallel bus slave interfaces.

CS Parallel

Bus

Slave

Interface

Serial Bus

Slave I/F

Switch

Timing

Control

and

Status

Registers

Slot

Power I/F

Card

Detection

CBT-Switch

Control

and

Slot Reset

Attention

Indicators

DATA 7–0

A 4–0

SDA

SCL

ADD 6–0

IDLEREQ

IDLEGNT

FRAME

IRDY

SREQ

SGNT

PCLK

PWRON/OFF

PWRFAULT

PWRGOOD

PRSNT2

PRSNT1

REQ64ON

CLKON

SLOTRST

SLOTREQ64

ATTN0

ATTN1

SYSM66EN

INTR

PRST

BUSON

M66EN

DETECT

SYSTEM INTERFACE SLOT INTERFACE

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

terminal assignments (120-terminal package)

PBM QUAD FLAT PACKAGE

TOP VIEW

PRST

PWRON/OFF[3]

100

101

102

103

104

105

106

107

108

109

110

111

112

113

114

115

116

117

118

119

120

30 61

RSVD

DETECT1[1]

DETECT0[1]

M66EN[1]

ATTN1[1]

ATTN0[1]

CLKON[1]

BUSON[1]

REQ64ON[1]

GND

REQ64ON[1]

SLOTRST[1]

PRSNT2[1]

PWRGOOD[1]

DETECT1[0]

DETECT0[0]

GND

M66EN[0]

ATTN1[0]

ATTN0[0]

CLKON[0]

BUSON[0]

RSVD

PWRFAULT[1]

ATTN0[3]

M66EN[3]

DETECT0[3]

SLOTREQ64[3]

SLOTREQ64[2]

SLOTREQ64[1]

SLOTREQ64[0]

GND

SREQ

SGNT

SMODE

PCLK

GND

IDLEREQ

IDLEGNT

FRAME

IRDY

INTR

SYSM66EN

GND

RD/SDA

WR/SCL

CLKON[3]

BUSON[3]

REQ64ON[3]

GND

REQ64ON[3]

SLOTRST[3]

PRSNT2[3]

PRSNT1[3]

GND

PWRGOOD[3]

DETECT1[2]

DETECT0[2]

M66EN[2]

ATTN1[2]

ATTN0[2]

CLKON[2]

GND

BUSON[2]

REQ640N[2]

REQ64ON[2]

SLOTRST[2]

PRSNT2[2]

PRSNT1[2]

PWRGOOD[2]

PWRFAULT[2]

PWRON/OFF[2]

RSVD

DATA7

DATA6

DATA4

DATA3

GND

DATA2

DATA1/ADD6

DATA0/ADD5

A4/ADD4

A2/ADD2

A1/ADD1

GND

PWRON/OFF[0]

PWRFAULT[0]

PWRGOOD[0]

PRSNT1[0]

PRSNT2[0]

SLOTRST[0]

REQ64ON[0]

VCC

ATTN1[3]

VCC5V

A3/ADD3

VCC

VCCP

VCC5V

DETECT1[3]

VCC5V

PRSNT1[1]

PWRON/OFF[1]

PWRFAULT[3]

DATA5

V5V

REQ64ON[0]

A0/ADD0

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

4POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

terminal assignments (128-terminal package)

PBK LOW-PROFILE QUAD FLAT PACKAGE

TOP VIEW

GND

A0/ADD0

101

102

100

30 67

RSVD

DETECT1[1]

DETECT0[1]

ATTN1[1]

ATTN0[1]

CLKON[1]

BUSON[1]

REQ64ON[1]

GND

REQ64ON[1]

SLOTRST[1]

PRSNT2[1]

PRSNT1[1]

PWRFAULT[1

PWRON/OFF[1]

DETECT1[0]

DETECT0[0]

GND

M66EN[0]

ATTN1[0]

ATTN0[0]

CLKON[0]

BUSON[0]

RSVD

ATTN1[3]

M66EN[3]

DETECT0[3]

DETECT1[3]

SLOTREQ64[3]

SLOTREQ64[2]

SLOTREQ64[1]

SLOTREQ64[0]

GND

SGNT

PRST

PCLK

GND

IDLEREQ

IDLEGNT

FRAME

IRDY

INTR

GND

SMODE

RD/SDA

CLKON[3]

BUSON[3]

REQ64ON[3]

GND

REQ64ON[3]

SLOTRST[3]

PRSNT2[3]

PRSNT1[3]

GND

PWRGOOD[3]

PWRON/OFF[3]

DETECT1[2]

DETECT0[2]

M66EN[2]

ATTN1[2]

ATTN0[2]

CLKON[2]

GND

BUSON[2]

REQ64ON[2]

PRSNT2[2]

PRSNT1[2]

PWRGOOD[2]

PWRFAULT[2]

RSVD

DATA7

DATA6

DATA5

DATA4

DATA3

GND

DATA2

DATA1/ADD6

DATA0/ADD5

A4/ADD4

A3/ADD3

A2/ADD2

PWRON/OFF[0]

PWRFAULT[0]

PWRGOOD[0]

PRSNT1[0]

PRSNT2[0]

SLOTRS[0]

REQ64ON[0]

VCC

VCC5V

WR/SCL

64 97

98 PWRON/OFF[2]

RSVD

103

104

105

106

107

108

109

110

111

112

113

114

115

116

117

118

119

120

121

122

123

124

125

126

127

128

ATTN0[3]

M66EN[1]

SREQ

VCC5V

PWRGOOD[1]

]

VCCP

SYSM66EN

VCC5V

PWRFAULT[3]

SLOTRST[2]

V5V

A1/ADD1

REQ64ON[0]

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

terminal assignments (144-terminal package)

PGE LOW-PROFILE QUAD FLAT PACKAGE

TOP VIEW

PRSNT1[2]

SLOTRST[1]

100

101

102

103

104

105

106

107

108

109

110

111

112

113

114

115

116

117

118

119

120

121

122

123

124

125

126

127

128

129

130

131

132

133

134

135

136

137

138

139

140

141

142

143

144

ATTN0[3]

M66EN[3]

GND

PCLK

DETECT0[3]

IDLEGNT

FRAME

IRDY

IDLEREQ

SYSM66EN

GND

SMODE

RSVD

DATA7

DATA6

DATA5

DATA3

GND

DATA2

DATA0/ADD5

A4/ADD4

A1/ADD1

A0/ADD0

GND

RSVD

ATTN0[0]

ATTN1[0]

M66EN[0]

GND

BUSON[0]

PRSNT1[1]

REQ64ON[1]

GND

REQ64ON[1]

ATTN0[1]

ATTN1[1]

M66EN[1]

RSVD

REQ64ON[2]

ATTN0[2]

ATTN1[2]

M66EN[2]

GND

REQ64ON[3]

PWRGOOD[3]

PWRON/OFF[2]

SREQ

CC5V

VCC

PWRFAULT[3]

VCC

CC5V

PWRFAULT[2]

PWRGOOD[2]

PRSNT2[2]

REQ64ON[2]

BUSON[2]

SLOTRST[2]

CLKON[2]

DETECT0[2]

VCC5V

PWRON/OFF[3]

DETECT1[2]

GND

PRSNT1[3]

PRSNT2[3]

SLOTRST[3]

REQ64ON[3]

BUSON[3]

CLKON[3]

RSVD

DATA4

DATA1/ADD6

VCC5V

A3/ADD3

A2/ADD2

PWRON/OFF[0]

VCC

PWRFAULT[0]

PWRGOOD[0]

PRSNT1[0]

PRSNT2[0]

SLOTRST[0]

REQ64ON[0]

RSVD

CLKON[0]

DETECT0[0]

DETECT1[0]

PWRON/OFF[1]

PWRFAULT[1]

PWRGOOD[1]

PRSNT2[1]

BUSON[1]

CLKON[1]

DETECT0[1]

DETECT1[1]

RSVD

ATTN1[3]

GND

DETECT1[3]

SLOTREQ64[3]

SLOTREQ64[2]

SLOTREQ64[1]

SLOTREQ64[0]

SGNT

PRST

CCP

INTR

CC5V

RD/SDA

WR/SCL

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

6POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

signal names by terminal name

Table 1. Signals Sorted Alphabetically by Terminal Name (120-Terminal Package)

TERMINAL NAME NO. TERMINAL NAME NO. TERMINAL NAME NO.

A0/ADD0 50 GND 17 RD/SDA 29

A1/ADD1 49 GND 26 REQ64ON[0] 59

A2/ADD2 48 GND 41 REQ64ON[1] 78

A3/ADD3 47 GND 51 REQ64ON[2] 98

A4/ADD4 45 GND 68 REQ64ON[3] 116

ATTN0[0] 65 GND 79 REQ64ON[0] 60

ATTN0[1] 83 GND 101 REQ64ON[1] 80

ATTN0[2] 103 GND 112 REQ64ON[2] 99

ATTN0[3] 1 GND 117 REQ64ON[3] 118

ATTN1[0] 66 IDLEGNT 19 RSVD 31

ATTN1[1] 84 IDLEREQ 18 RSVD 32

ATTN1[2] 104 INTR 24 RSVD 33

ATTN1[3] 2 INTR 23 RSVD 61

BUSON[0] 63 IRDY 21 RSVD 62

BUSON[1] 81 M66EN[0] 67 RSVD 89

BUSON[2] 100 M66EN[1] 86 RSVD 90

BUSON[3] 119 M66EN[2] 105 SGNT 13

CLKON[0] 64 M66EN[3] 3 SLOTREQ64[0] 10

CLKON[1] 82 PCLK 16 SLOTREQ64[1] 9

CLKON[2] 102 PRSNT1[0] 55 SLOTREQ64[2] 8

CLKON[3] 120 PRSNT1[1] 75 SLOTREQ64[3] 7

CS 34 PRSNT1[2] 94 SLOTRST[0] 58

DATA0/ADD5 44 PRSNT1[3] 113 SLOTRST[1] 77

DATA1/ADD6 43 PRSNT2[0] 57 SLOTRST[2] 97

DATA2 42 PRSNT2[1] 76 SLOTRST[3] 115

DATA3 40 PRSNT2[2] 96 SMODE 27

DATA4 39 PRSNT2[3] 114 SREQ 12

DATA5 38 PRST 14 SYSM66EN 25

DATA6 37 PWRFAULT[0] 53 VCC 6

DATA7 35 PWRFAULT[1] 72 VCC 36

DETECT0[0] 69 PWRFAULT[2] 92 VCC 56

DETECT0[1] 87 PWRFAULT[3] 110 VCC 85

DETECT0[2] 106 PWRGOOD[0] 54 VCC 95

DETECT0[3] 4 PWRGOOD[1] 73 VCC5V 15

DETECT1[0] 70 PWRGOOD[2] 93 VCC5V 28

DETECT1[1] 88 PWRGOOD[3] 111 VCC5V 46

DETECT1[2] 108 PWRON/OFF[0] 52 VCC5V 74

DETECT1[3] 5 PWRON/OFF[1] 71 VCC5V 107

FRAME 20 PWRON/OFF[2] 91 VCCP 22

GND 11 PWRON/OFF[3] 109 WR/SCL 30

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

signal names by terminal number

Table 2. Signals Sorted Numerically by Terminal Number (120-Terminal Package)

NO. TERMINAL NAME NO. TERMINAL NAME NO. TERMINAL NAME

1 ATTN0[3] 41 GND 81 BUSON[1]

2 ATTN1[3] 42 DATA2 82 CLKON[1]

3 M66EN[3] 43 DATA1/ADD6 83 ATTN0[1]

4 DETECT0[3] 44 DATA0/ADD5 84 ATTN1[1]

5 DETECT1[3] 45 A4/ADD4 85 VCC

6 VCC 46 VCC5V 86 M66EN[1]

7 SLOTREQ64[3] 47 A3/ADD3 87 DETECT0[1]

8 SLOTREQ64[2] 48 A2/ADD2 88 DETECT1[1]

9 SLOTREQ64[1] 49 A1/ADD1 89 RSVD

10 SLOTREQ64[0] 50 A0/ADD0 90 RSVD

11 GND 51 GND 91 PWRON/OFF[2]

12 SREQ 52 PWRON/OFF[0] 92 PWRFAULT[2]

13 SGNT 53 PWRFAULT[0] 93 PWRGOOD[2]

14 PRST 54 PWRGOOD[0] 94 PRSNT1[2]

15 VCC5V 55 PRSNT1[0] 95 VCC

16 PCLK 56 VCC 96 PRSNT2[2]

17 GND 57 PRSNT2[0] 97 SLOTRST[2]

18 IDLEREQ 58 SLOTRST[0] 98 REQ64ON[2]

19 IDLEGNT 59 REQ64ON[0] 99 REQ64ON[2]

20 FRAME 60 REQ64ON[0] 100 BUSON[2]

21 IRDY 61 RSVD 101 GND

22 VCCP 62 RSVD 102 CLKON[2]

23 INTR 63 BUSON[0] 103 ATTN0[2]

24 INTR 64 CLKON[0] 104 ATTN1[2]

25 SYSM66EN 65 ATTN0[0] 105 M66EN[2]

26 GND 66 ATTN1[0] 106 DETECT0[2]

27 SMODE 67 M66EN[0] 107 VCC5V

28 VCC5V 68 GND 108 DETECT1[2]

29 RD/SDA 69 DETECT0[0] 109 PWRON/OFF[3]

30 WR/SCL 70 DETECT1[0] 110 PWRFAULT[3]

31 RSVD 71 PWRON/OFF[1] 111 PWRGOOD[3]

32 RSVD 72 PWRFAULT[1] 112 GND

33 RSVD 73 PWRGOOD[1] 113 PRSNT1[3]

34 CS 74 VCC5V 114 PRSNT2[3]

35 DATA7 75 PRSNT1[1] 115 SLOTRST[3]

36 VCC 76 PRSNT2[1] 116 REQ64ON[3]

37 DATA6 77 SLOTRST[1] 117 GND

38 DATA5 78 REQ64ON[1] 118 REQ64ON[3]

39 DATA4 79 GND 119 BUSON[3]

40 DATA3 80 REQ64ON[1] 120 CLKON[3]

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

8POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

signal names by terminal name

Table 3. Signals Sorted Alphabetically by Terminal Name (128-Terminal Package)

TERMINAL NAME NO. TERMINAL NAME NO. TERMINAL NAME NO. TERMINAL NAME NO.

A0/ADD0 53 DETECT0[2] 113 NC 97 REQ64ON[3] 125

A1/ADD1 52 DETECT0[3] 5NC128 RSVD 34

A2/ADD2 51 DETECT1[0] 75 PCLK 17 RSVD 35

A3/ADD3 50 DETECT1[1] 93 PRSNT1[0] 58 RSVD 36

A4/ADD4 48 DETECT1[2] 115 PRSNT1[1] 80 RSVD 66

ATTN0[0] 70 DETECT1[3] 6 PRSNT1[2] 101 RSVD 67

ATTN0[1] 88 FRAME 21 PRSNT1[3] 120 RSVD 94

ATTN0[2] 110 GND 12 PRSNT2[0] 60 RSVD 95

ATTN0[3] 2 GND 18 PRSNT2[1] 81 SGNT 14

ATTN1[0] 71 GND 27 PRSNT2[2] 103 SLOTREQ64[0] 11

ATTN1[1] 89 GND 44 PRSNT2[3] 121 SLOTREQ64[1] 10

ATTN1[2] 111 GND 54 PRST 15 SLOTREQ64[2] 9

ATTN1[3] 3 GND 73 PWRFAULT[0] 56 SLOTREQ64[3] 8

BUSON[0] 68 GND 84 PWRFAULT[1] 77 SLOTRST[0] 61

BUSON[1] 86 GND 108 PWRFAULT[2] 99 SLOTRST[1] 82

BUSON[2] 107 GND 119 PWRFAULT[3] 117 SLOTRST[2] 104

BUSON[3] 126 GND 124 PWRGOOD[0] 57 SLOTRST[3] 122

CLKON[0] 69 IDLEGNT 20 PWRGOOD[1] 78 SMODE 28

CLKON[1] 87 IDLEREQ 19 PWRGOOD[2] 100 SREQ 13

CLKON[2] 109 INTR 25 PWRGOOD[3] 118 SYSM66EN 26

CLKON[3] 127 INTR 24 PWRON/OFF[0] 55 VCC 7

CS 37 IRDY 22 PWRON/OFF[1] 76 VCC 39

DATA0/ADD5 47 M66EN[0] 72 PWRON/OFF[2] 98 VCC 59

DATA1/ADD6 46 M66EN[1] 91 PWRON/OFF[3] 116 VCC 90

DATA2 45 M66EN[2] 112 RD/SDA 30 VCC 102

DATA3 43 M66EN[3] 4 REQ64ON[0] 62 VCC5V 16

DATA4 42 NC 1 REQ64ON[1] 83 VCC5V 29

DATA5 41 NC 32 REQ64ON[2] 105 VCC5V 49

DATA6 40 NC 33 REQ64ON[3] 123 VCC5V 79

DATA7 38 NC 64 REQ64ON[0] 63 VCC5V 114

DETECT0[0] 74 NC 65 REQ64ON[1] 85 VCCP 23

DETECT0[1] 92 NC 96 REQ64ON[2] 106 WR/SCL 31

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

signal names by terminal number

Table 4. Signals Sorted Numerically by Terminal Number (128-Terminal Package)

NO. TERMINAL NAME NO. TERMINAL NAME NO. TERMINAL NAME NO. TERMINAL NAME

1 NC 33 NC 65 NC 97 NC

2 ATTN0[3] 34 RSVD 66 RSVD 98 PWRON/OFF[2]

3 ATTN1[3] 35 RSVD 67 RSVD 99 PWRFAULT[2]

4 M66EN[3] 36 RSVD 68 BUSON[0] 100 PWRGOOD[2]

5 DETECT0[3] 37 CS 69 CLKON[0] 101 PRSNT1[2]

6 DETECT1[3] 38 DATA7 70 ATTN0[0] 102 VCC

7 VCC 39 VCC 71 ATTN1[0] 103 PRSNT2[2]

8 SLOTREQ64[3] 40 DATA6 72 M66EN[0] 104 SLOTRST[2]

9 SLOTREQ64[2 41 DATA5 73 GND 105 REQ64ON[2]

10 SLOTREQ64[1] 42 DATA4 74 DETECT0[0] 106 REQ64ON[2]

11 SLOTREQ64[0] 43 DATA3 75 DETECT1[0] 107 BUSON[2]

12 GND 44 GND 76 PWRON/OFF[1] 108 GND

13 SREQ 45 DATA2 77 PWRFAULT[1] 109 CLKON[2]

14 SGNT 46 DATA1/ADD6 78 PWRGOOD[1] 110 ATTN0[2]

15 PRST 47 DATA0/ADD5 79 VCC5V 111 ATTN1[2]

16 VCC5V 48 A4/ADD4 80 PRSNT1[1] 112 M66EN[2]

17 PCLK 49 VCC5V 81 PRSNT2[1] 113 DETECT0[2]

18 GND 50 A3/ADD3 82 SLOTRST[1] 114 VCC5V

19 IDLEREQ 51 A2/ADD2 83 REQ64ON[1] 115 DETECT1[2]

20 IDLEGNT 52 A1/ADD1 84 GND 116 PWRON/OFF[3]

21 FRAME 53 A0/ADD0 85 REQ64ON[1] 117 PWRFAULT[3]

22 IRDY 54 GND 86 BUSON[1] 118 PWRGOOD[3]

23 VCCP 55 PWRON/OFF[0] 87 CLKON[1] 119 GND

24 INTR 56 PWRFAULT[0] 88 ATTN0[1] 120 PRSNT1[3]

25 INTR 57 PWRGOOD[0] 89 ATTN1[1] 121 PRSNT2[3

26 SYSM66EN 58 PRSNT1[0] 90 VCC 122 SLOTRST[3]

27 GND 59 VCC 91 M66EN[1] 123 REQ64ON[3]

28 SMODE 60 PRSNT2[0] 92 DETECT0[1] 124 GND

29 VCC5V 61 SLOTRST[0] 93 DETECT1[1] 125 REQ64ON[3]

30 RD/SDA 62 REQ64ON[0] 94 RSVD 126 BUSON[3]

31 WR/SCL 63 REQ64ON[0] 95 RSVD 127 CLKON[3]

32 NC 64 NC 96 NC 128 NC

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

10 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

signal names by terminal name

Table 5. Signals Sorted Alphabetically by Terminal Name (144-Terminal Package)

TERMINAL NAME NO. TERMINAL NAME NO. TERMINAL NAME NO. TERMINAL NAME NO.

A0/ADD0 59 DETECT1[2] 129 NC 78 REQ64ON[3] 137

A1/ADD1 58 DETECT1[3] 8NC103 REQ64ON[0] 72

A2/ADD2 57 FRAME 23 NC 105 REQ64ON[1] 95

A3/ADD3 56 GND 14 NC 107 REQ64ON[2] 120

A4/ADD4 54 GND 20 NC 110 REQ64ON[3] 140

ATTN0[0] 80 GND 29 NC 112 RSVD 37

ATTN0[1] 98 GND 50 NC 114 RSVD 39

ATTN0[2] 124 GND 60 NC 139 RSVD 41

ATTN0[3] 1 GND 83 NC 141 RSVD 73

ATTN1[0] 81 GND 94 NC 143 RSVD 75

ATTN1[1] 99 GND 122 PCLK 19 RSVD 106

ATTN1[2] 125 GND 133 PRSNT1[0] 64 RSVD 108

ATTN1[3] 3 GND 138 PRSNT1[1] 90 SGNT 16

BUSON[0] 77 IDLEGNT 22 PRSNT1[2] 115 SLOTREQ64[0] 13

BUSON[1] 96 IDLEREQ 21 PRSNT1[3] 134 SLOTREQ64[1] 12

BUSON[2] 121 INTR 27 PRSNT2[0] 66 SLOTREQ64[2] 11

BUSON[3] 142 INTR 26 PRSNT2[1] 91 SLOTREQ64[3] 10

CLKON[0] 79 IRDY 24 PRSNT2[2] 117 SLOTRST[0] 68

CLKON[1] 97 M66EN[0] 82 PRSNT2[3] 135 SLOTRST[1] 92

CLKON[2] 123 M66EN[1] 101 PRST 17 SLOTRST[2] 118

CLKON[3] 144 M66EN[2] 126 PWRFAULT[0] 62 SLOTRST[3] 136

CS 43 M66EN[3] 5 PWRFAULT[1] 87 SMODE 30

DATA0/ADD5 53 NC 2 PWRFAULT[2] 111 SREQ 15

DATA1/ADD6 52 NC 4 PWRFAULT[3] 131 SYSM66EN 28

DATA2 51 NC 6 PWRGOOD[0] 63 VCC 9

DATA3 49 NC 31 PWRGOOD[1] 88 VCC 45

DATA4 48 NC 33 PWRGOOD[2] 113 VCC 65

DATA5 47 NC 35 PWRGOOD[3] 132 VCC 100

DATA6 46 NC 38 PWRON/OFF[0] 61 VCC 116

DATA7 44 NC 40 PWRON/OFF[1] 86 VCC5V 18

DETECT0[0] 84 NC 42 PWRON/OFF[2] 109 VCC5V 32

DETECT0[1] 102 NC 67 PWRON/OFF[3] 130 VCC5V 55

DETECT0[2] 127 NC 69 RD/SDA 34 VCC5V 89

DETECT0[3] 7NC71 REQ64ON[0] 70 VCC5V 128

DETECT1[0] 85 NC 74 REQ64ON[1] 93 VCCP 25

DETECT1[1] 104 NC 76 REQ64ON[2] 119 WR/SCL 36

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

signal names by terminal number

Table 6. Signals Sorted Numerically by Terminal Number (144-Terminal Package)

NO. TERMINAL NAME NO. TERMINAL NAME NO. TERMINAL NAME NO. TERMINAL NAME

1 ATTN0[3] 37 RSVD 73 RSVD 109 PWRON/OFF[2]

2 NC 38 NC 74 NC 110 NC

3 ATTN1[3] 39 RSVD 75 RSVD 111 PWRFAULT[2]

4 NC 40 NC 76 NC 112 NC

5 M66EN[3] 41 RSVD 77 BUSON[0] 113 PWRGOOD[2]

6 NC 42 NC 78 NC 114 NC

7 DETECT0[3] 43 CS 79 CLKON[0] 115 PRSNT1[2]

8 DETECT1[3] 44 DATA7 80 ATTN0[0] 116 VCC

9 VCC 45 VCC 81 ATTN1[0] 117 PRSNT2[2]

10 SLOTREQ64[3] 46 DATA6 82 M66EN[0] 118 SLOTRST[2]

11 SLOTREQ64[2] 47 DATA5 83 GND 119 REQ64ON[2]

12 SLOTREQ64[1] 48 DATA4 84 DETECT0[0] 120 REQ64ON[2]

13 SLOTREQ64[0] 49 DATA3 85 DETECT1[0] 121 BUSON[2]

14 GND 50 GND 86 PWRON/OFF[1] 122 GND

15 SREQ 51 DATA2 87 PWRFAULT[1] 123 CLKON[2]

16 SGNT 52 DATA1/ADD6 88 PWRGOOD[1] 124 ATTN0[2]

17 PRST 53 DATA0/ADD5 89 VCC5V 125 ATTN1[2]

18 VCC5V 54 A4/ADD4 90 PRSNT1[1] 126 M66EN[2]

19 PCLK 55 VCC5V 91 PRSNT2[1] 127 DETECT0[2]

20 GND 56 A3/ADD3 92 SLOTRST[1] 128 VCC5V

21 IDLEREQ 57 A2/ADD2 93 REQ64ON[1] 129 DETECT1[2]

22 IDLEGNT 58 A1/ADD1 94 GND 130 PWRON/OFF[3]

23 FRAME 59 A0/ADD0 95 REQ64ON[1] 131 PWRFAULT[3]

24 IRDY 60 GND 96 BUSON[1] 132 PWRGOOD[3]

25 VCCP 61 PWRON/OFF[0] 97 CLKON[1] 133 GND

26 INTR 62 PWRFAULT[0] 98 ATTN0[1] 134 PRSNT1[3]

27 INTR 63 PWRGOOD[0] 99 ATTN1[1] 135 PRSNT2[3]

28 SYSM66EN 64 PRSNT1[0] 100 VCC 136 SLOTRST[3]

29 GND 65 VCC 101 M66EN[1] 137 REQ64ON[3]

30 SMODE 66 PRSNT2[0] 102 DETECT0[1] 138 GND

31 NC 67 NC 103 NC 139 NC

32 VCC5V 68 SLOTRST[0] 104 DETECT1[1] 140 REQ64ON[3]

33 NC 69 NC 105 NC 141 NC

34 RD/SDA 70 REQ64ON[0] 106 RSVD 142 BUSON[3]

35 NC 71 NC 107 NC 143 NC

36 WR/SCL 72 REQ64ON[0] 108 RSVD 144 CLKON[3]

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

12 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

Terminal Functions

This section describes the HPC3130A terminal functions. The terminals are grouped in tables by function.

power supply terminal functions

TERMINAL

NAME NO.

120

NO.

128

NO.

144

I/O FUNCTION

GND 11, 17, 26, 41, 51,

68, 79, 101, 112, 117

12, 18, 27, 44, 54,

73, 84, 108, 119, 124

14, 20, 29, 50, 60,

83, 94, 122, 133, 138

IDevice ground terminals

VCC 6, 36, 56, 85, 95 7, 39, 59, 90, 102 9, 45, 65, 100, 116 I 3.3-V power supply

VCC5V 15, 28, 46, 74, 107 16, 29, 49, 79, 114 18, 32, 55, 89, 128 I 5-V clamp-rail voltage supply

VCCP 22 23 25 I Clamp rail voltage for PCI signaling (5V or 3.3V)

control bus interface

TERMINAL

NAME NO.

120

NO.

128

NO.

144

I/O FUNCTION

A2/ADD2

A1/ADD1

A0/ADD0

Parallel bus address. These terminals are address inputs in generic parallel bus cycles and are

only used when the SMODE is input low. These lower address terminals select one of the eight

registers for read/write access.

Serial bus address select. These terminals indicate the full serial bus address of the HPC3130A

when the SMODE is input high.

A4/ADD4

A3/ADD3

56 I

Parallel bus address. These terminals are address inputs in generic parallel bus cycles, and are

only used when SMODE is input low. These upper address terminals select one of four hot-plug

slots supported by the HPC3130A.

Serial bus address select. These terminals indicate the full serial bus address of the HPC3130A

when the SMODE is input high.

CS 34 37 43 I

Chip selection. This active low input selects the HPC3130A chip as addressed in the current

generic parallel bus cycle. This chip input is only valid if the SMODE is input low. Multiple

HPC3130A chips may exist in a system with external logic driving this signal.

DATA1/ADD6

DATA0/ADD5

53 I/O

Parallel bus data. This bus is the data bus in generic parallel bus cycles and is selected when the

SMODE is input low. The data path is used during both read and write transactions to internal

registers when the parallel control bus interface is implemented.

Serial bus address selection. These terminals indicate the full serial bus address of the

HPC3130A when the SMODE is input high.

DATA7

DATA6

DATA5

DATA4

DATA3

DATA2

I/O

Parallel bus data. This bus is the data bus in generic parallel bus cycles and is selected when the

SMODE is input low. The data path is used during both read and write transactions to internal

registers when the parallel control bus interface is implemented.

RD/SDA 29 30 34 I/O

Read selection. This terminal indicates a register read cycle when the SMODE input is low and

the CS terminal input is asserted. This is used to read an internal HPC3130A register.

Serial bus data. This terminal signals the serial bus data when the SMODE input is high. It is used

during internal register read and write transactions.

WR/SCL 30 31 36 I

Write selection. This terminal indicates a register write cycle when the SMODE input is low and

the CS terminal input is asserted. This input is used to write to an internal HPC3130A register.

Serial bus clock. This terminal inputs serial bus clock in when the SMODE input is high. It is used

during internal register read and write transactions.

HPC3130A

PCI HOT PLUG CONTROLLER

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Terminal Functions (Continued)

system interface

TERMINAL

NAME NO.

120

NO.

128

NO.

144

I/O FUNCTION

FRAME 20 21 23 I

Frame. This input and the IRDY input indicate that the PCI bus is idle. When the HPC3130A

senses the PCI bus is idle after IDLEGNT is low, a hot-plug slot can be connected to the PCI

bus. This input must be wired to a valid logic level if the bus idling procedure is not implemented.

IDLEGNT 19 20 22 I

Idle grant. This input indicates when the PCI bus is idled by the HOST-PCI bridge after a

request is made by IDLEREQ. The protocol is identical to PCI request/grant. This input must be

wired to a valid logic level if the bus idling procedure is not implemented.

IDLEREQ 18 19 21 O

Idle request. This output is driven to request the HOST-PCI bridge to idle the PCI bus before

connecting a hot-plug slot. The protocol is identical to PCI request/grant. A pullup resistor must

be implemented on this terminal if the bus idling procedure is not implemented.

INTR 24 25 27 O

System interrupt. This output provides a system interrupt. The HPC3130A can be programmed

to assert this interrupt under various conditions, which may be serviced by the hot-plug service.

Furthermore, the event status/enable state is compliant with the

ACPI Specification

and, as a

result, supports ACPI control methods for switching the HPC3130A.

INTR 23 24 26 O

System interrupt. This open drain output provides a system interrupt. The HPC3130A can be

programmed to assert this interrupt under various conditions, which may be serviced by the

hot-plug. Furthermore, the event status/enable state is compliant with the

ACPI Specification

and, as a result, supports ACPI control methods for switching the HPC3130A.

IRDY 21 22 24 I

Initiator ready. This and the FRAME input indicate that the PCI bus is idle. When the HPC3130A

senses the PCI bus is idle after IDLEGNT is low, a hot-plug slot may be connected to the PCI

bus. This input must be wired to a valid logic level if the bus idling procedure is not implemented.

PCLK 16 17 19 I PCI clock input. These terminals provide the PCI clock to the HPC3130A, which uses it only for

activity indicator timing, IDLEREQ/IDLEGNT protocol, and connection sequencing.

PRST 14 15 17 I

PCI reset. This signal provides the PCI reset to the HPC3130A. After a PCI reset, the

HPC3130A resides in a state where all slots are enabled, as in a non-hot-plug system. The

HPC3130A passes PCI resets from the host to all hot-plug slots.

SGNT 13 14 16 O

Secondary grant. This output provides a scheme to cascade a secondary HPC3130A device in

order to provide more than four slots. The SGNT output from the primary HPC3130A is input to

the IDLEGNT terminal for the secondary HPC3130A. After the secondary HPC3130A requests

the primary HPC3130A to idle the bus, the primary HPC3130A arbitrates for the bus using

IDLEREQ. Once IDLEGNT is asserted, the primary HPC3130A asserts its SGNT output. This

indicates to the secondary HPC3130A device that it can connect to the bus.

SMODE 27 28 30 I

Serial bus mode. When this input is asserted high, the internal HPC3130A registers are

accessible through the serial bus interface; otherwise, they are accessed through the generic

parallel bus interface. This input selects the control bus interface.

SREQ 12 13 15 I

Secondary request. This input provides a scheme to cascade a second HPC3130A device in

order to provide more than four slots. The IDLEREQ from the second HPC3130A device is

input to the SREQ terminal of the primary HPC3130A. If the second HPC3130A device

arbitrates for the bus by asserting its IDLEREQ output, this scheme causes the primary

HPC3130A to assert its IDLEREQ. If cascading is not used, this input is pulled high.

SYSM66EN 25 26 28 I/O

PCI bus frequency indicator. This signal indicates the PCI clock frequency requirements of the

hot-plug slots, and must be tied to the system PCI bus M66EN signal. The output from this

terminal only changes state after a PCI reset and is only required in a 66-MHz system.

HPC3130A

PCI HOT PLUG CONTROLLER

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Terminal Functions (Continued)

slot control and status functions

TERMINAL

NAME NO.

120

NO.

128

NO.

144

I/O FUNCTION

ATTN0[3]

ATTN0[2]

ATTN0[1]

ATTN0[0]

ATTN1[3]

ATTN1[2]

ATTN1[1]

ATTN1[0]

103

104

110

111

124

125

Attention indicators. These two outputs are provided per slot as attention indicators and can

be independently programmed to drive high, low, fast blink, and slow blink. The timer is

based on the PCI clock frequency and the state of SYSM66EN.

BUSON[3]

BUSON[2]

BUSON[1]

BUSON[0]

119

100

126

107

142

121

CBT switch control for PCI bus. This output controls the CBT switch that connects the

hot-plug slot to the system PCI bus. This output is only driven by the HPC3130A under

programmed control.

CLKON[3]

CLKON[2]

CLKON[1]

CLKON[0]

120

102

127

109

144

123

PCI clock connection control. This output is used to control the CBT switch or clock driver

that connects the hot-plug slot to the system PCI clock. This output is only driven by the

HPC3130A under programmed control.

DETECT0[3]

DETECT0[2]

DETECT0[1]

DETECT0[0]

DETECT1[3]

DETECT1[2]

DETECT1[1]

DETECT1[0]

106

108

113

115

127

102

129

104

Card detection signals. These two card detect input signals, DETECT0 and DETECT1, are

provided as additional card detection signals to the PRSNT1 and PRSNT2. Since only one

present input must be tied to ground to indicate a card is present per the

PCI Specification

these optional inputs are provided for designers of a more mechanically robust system. If the

protection enable bit is set to 1 in the general configuration register, the HPC3130A does not

power a hot-plug slot unless DETECT0 and DETECT1 are input low. A design not

implementing additional card detection must tie these signals to ground. When this feature is

utilized, the HPC3130A guarantees that power can not be applied to an empty slot or a slot

with a partially inserted card.

M66EN[3]

M66EN[2]

M66EN[1]

M66EN[0]

105

112

126

101

PCI bus frequency indicator. This signal indicates the PCI clock frequency requirements of

the hot-plug slots and is only required in a 66-MHz system (two slot maximum electrical

loading limits). The two slot interfaces that provide the M66EN terminals are sensed at PCI

reset and are driven afterwards.

PRSNT1[3]

PRSNT1[2]

PRSNT1[1]

PRSNT1[0]

PRSNT2[3]

PRSNT2[2]

PRSNT2[1]

PRSNT2[0]

113

114

120

101

121

103

134

115

135

117

Present signals. These inputs are provided by hot-plug slots to indicate that an add-in card is

physically present in the slot and to power requirements to the system. Only one of these

signals must be tied to ground to indicate a card is present in an expansion slot. A set of

PRSNT1 and PRSNT2 inputs are provided for each hot-plug slot.

PWRFAULT[3]

PWRFAULT[2]

PWRFAULT[1]

PWRFAULT[0]

110

117

131

111

Power fault. This input is provided per slot power switch to indicate if there is a power fault.

The HPC3130A can be programmed to generate an interrupt through INTR when this input

is asserted.

PWRGOOD[3]

PWRGOOD[2]

PWRGOOD[1]

PWRGOOD[0]

111

118

100

132

113

Power good. This input is provided per slot power switch to indicate when power is

successfully switched. The HPC3130A can be programmed to generate an interrupt through

INTR when this input is asserted.

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

Terminal Functions (Continued)

slot control and status functions (continued)

TERMINAL

NAME NO.

120

NO.

128

NO.

144

I/O FUNCTION

PWRON/OFF[3]

PWRON/OFF[2]

PWRON/OFF[1]

PWRON/OFF[0]

109

116

130

109

OPower ON/OFF. This output is provided per slot and is driven to the power switch to control

the slot power state.

REQ64ON[3]

REQ64ON[2]

REQ64ON[1]

REQ64ON[0]

116

123

105

137

119

CBT switch control for SLOTREQ64. A CBT switch can be implemented to reduce trace

loading of the additional REQ64 signal inherent to the HPC3130A controller. This output

can be used to control the CBT switch. This output is only driven by the HPC3130A under

programmed control.

REQ64ON[3]

REQ64ON[2]

REQ64ON[1]

REQ64ON[0]

118

125

106

140

120

CBT switch control for SLOTREQ64. A CBT switch can be implemented to reduce trace

loading of the additional REQ64 signal inherent to the HPC3130A controller. This output

can be used to control the CBT switch. This output is only driven by the HPC3130A under

programmed control.

SLOTREQ64[3]

SLOTREQ64[2]

SLOTREQ64[1]

SLOTREQ64[0]

Slot request 64. This output is driven in conjunction with SLOTRST to the hot-plug slot to

indicate to option cards whether or not they are plugged into a 64-bit slot. If a 64-bit device

is plugged into a 32-bit slot, then it must ensure that its high-word path inputs do not

oscillate and that there is not a significant power drain through the input buffer. This output

is only driven by the HPC3130A under programmed control.

SLOTRST[3]

SLOTRST[2]

SLOTRST[1]

SLOTRST[0]

115

122

104

136

118

Slot PCI reset. This output is driven to the hot-plug slot to reset it after power up. When a

card is inserted into a hot-plug slot it must be reset independent of the other PCI devices on

the bus. This output is only driven by the HPC3130A under programmed control.

HPC3130A applications

This section discusses the various features of the HPC3130A in detail, and presents design considerations

including a general connection sequencing guideline.

system implementation

Figure 1 illustrates the HPC3130A implementation. The PCI bus signals are switched to the hot–plug PCI slot

by the BUSON output, which controls a CBT switch. The PCI clock, PCI reset, M66EN, and REQ64 must not

be routed through the CBT switch. The HPC3130A drives the slot PCI reset and SLOTREQ64, which can be

controlled by internal HPC3130A registers. The SLOTREQ64 requires special consideration during reset, as

described. The PCI clock to the slot is driven by a clock driver, which is enabled by the HPC3130A CLKON

output.

The HPC3130A also provides other features such as mechanical detection circuits, attention indicators, and

interrupt signaling. The mechanical detection circuitry using the DETECT[1,0] inputs is displayed as a dotted

line and is an optional feature. Two attention indicator outputs, ATTN[1,0], are provided: one indicator to draw

the attention of the user to a particular slot for insertion/removal, and one optional indicator that can be used

to indicate fault conditions. Additional features, such as 66-MHz capability and automatic sequencing, are

discussed in the following sections.

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

16 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

8–BIT

PORT

HOST/PCI

INTR

PCLK

PRST

SYSM66EN

BUSON CBT–SW

CBT–SW

CLKON

CBT–SW

REQ64ON

SLOTREQ64

M66EN

PRSNT(1–2)

SLOTRST

PWRON/OFF

PERFAULT

PWRGOOD

PWR–SW

DETECT(0–1)

ATTN(0–1)

FRAME

IRDY

IDLEREQ

IDLEGNT

HPC–PCI

PCI Bus

PCI Bus Less PRST and REQ64

Motherboard

PCI Device

Figure 1. HPC3130A Implementation

The HPC3130A internal registers can be accessed through either a two-wire serial interface or an 8-bit generic

parallel bus (ISA-like). The above figure illustrates the 8-bit port configuration. Not shown in the diagram is the

SMODE chip input that must be wired low to indicate parallel bus interface mode. Also not shown in the diagram

is the external chip-select logic required to select the HPC3130A in ISA bus cycles.

serial interface

The internal registers can be accessed either through a two-wire serial interface or through an 8-bit generic

parallel interface. The SMODE input selects one of these modes.

The HPC3130A implements a two-pin serial slave interface with one clock signal (SCL) and one data signal

(SDA). This serial interface can operate with a serial clock frequency up to 400 kHz. Both SCL and SDA require

pullup resistors for the serial slave interface to function properly.

All data transfers are initiated by the serial bus master. The beginning of a data transfer is indicated by a START

condition (S) when the SDA line transitions to a low state while SCL is in a high state as illustrated in Figure 2.

The end of a requested data transfer is indicated by a STOP condition (P), which is the low-to-high transition

of SDA while SCL is in the high state. Data on SDA must remain stable during the high state of the SCL signal.

Changes on the SDA signal during the high state of SCL will be interpreted as control signals, that is, a START

or STOP condition.

The SCL is an input into the HPC3130A and SDA is bidirectional.

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

SDA

SCL

Start Condition Stop Condition Change of

Data Allowed

Data Line Stable, Data Valid

Figure 2. Serial Bus Start/Stop Conditions and Bit Transfers

Data is transferred on the bus in 8-bit bytes. The number of bytes that can be transmitted during a data transfer

is unlimited; however, each byte must be completed with an acknowledge bit. An acknowledge (ACK) is

indicated by the receiver pulling down the SDA signal so that it remains low during the high state of the SCL

signal as shown in Figure 3.

SCL From

Master 123 789

SDA Output

By Transmitter

SDA Output

By Receiver

Figure 3. Serial Bus Protocol – Acknowledge

The HPC3130A serial bus slave interface protocol for write transactions is illustrated in Figure 4. The R/W

command bit is set to zero to indicate a write transaction. For a write operation, the HPC3130A requires a word

address field after the slave address. This address field is comprised of eight bits. Upon receipt of the word

address, the HPC3130A responds with an acknowledge, and waits for the next eight bits of data, again

responding with an acknowledge. After all the data bytes are transferred, the master then terminates the transfer

by generating a STOP condition. The device automatically increments the address for subsequent data words.

After the receipt of each word, the low order address bits are internally incremented by one.

Sb6 b4b5 b3 b2 b1 b0 0 b7 b6 b5 b4 b3 b2 b1 b0AA

Slave Address Word Address

R/W

S/P = Start/stop conditionA = Slave acknowledgment

b7 b6 b4b5 b3 b2 b1 b0 A P

Data Byte

Figure 4. Serial Bus Protocol – Byte Write

A byte read operation is illustrated in Figure 5. The read protocol is very similar to the write protocol, except the

R/W command bit must be set to one to indicate a read data transfer. First the master issues a write command

that includes the START condition and the slave address field (with the R/W bit set to write), followed by the

address of the word it is to read. This procedure sets the internal address counter of the HPC3130A to the

desired address. After the word address acknowledgment is received by the master, the master immediately

reissues a START condition followed by another slave address field with the R/W bit set to read. The HPC3130A

responds with an acknowledgment and transmits the eight data bits stored in the addressed location. If the

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

18 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

master responds with an acknowledge signal, indicating that it requires additional data, the HPC3130A

continues to output data for each received acknowledge signal. The master terminates the sequential read

operation by not responding with an acknowledge signal, and issues a STOP condition.

b7Sb6 b4b5 b3 b2 b1 b0 0 b7 b6 b5 b4 b3 b2 b1 b0AA

Slave Address Word Address

R/W

S/P = Start/stop conditionA = Slave acknowledgment

b6 b4b5 b3 b2 b1 b0 1 A

Data Byte

M = Master acknowledgment

S b6 b4b5 b3 b2 b1 b0 M Pb6 b4b5 b3 b2 b1 b0 M P

Slave Address

R/W

Restart StopStart

Figure 5. Serial Bus Protocol – Byte Read

parallel interface

The HPC3130A also implements an 8-bit parallel interface mode. When this mode is selected, the HPC3130A

internal register addressed by the A[4:0] inputs can be accessed for a read/write transaction using the CS, RD,

WR strobes. The following signals have pullups on the mother board: IO16, M16, NOWS, CHRDY, MEMR,

MEMW, IOR, IOW, SD[15:0] to implement default states. Figure 6 shows write access using the default 8-bit

standard ISA bus cycle with four wait states. A read cycle is similar.

BCLK

A(0–4)

D(0–7)

Figure 6. Parallel Bus Write Cycle

connection sequencing

Before an add-in card is hot plugged and made available to the slot, the various pins in the HPC3130A have

to be controlled in a specific sequence. The HPC3130A provides the software interface to sequence the power

to the slot, clocks, and signals to the add-in cards that are being live inserted. The switch-timing block is used

to control the exact timing when the CBT switches are enabled.

The initial software sequencing is done by setting individual bits in the hot plug control register in the following

sequence. First, the SLTPWR_CTL bit is set high to drive the PWRON/OFF signal high. After the power to the

slot is applied, the SLOTRST_O bit is set low to drive the SLOTRST output. Next the CLKON_O bit is set low

to enable the PCI clock to the slot. Also, the REQ64_O bit is set to a value of 0 and the SLOTREQ64 bit is set

to indicate to the add-in card whether it is inserted into a 64-bit or 32-bit slot. SLOTREQ64 is set low for a 64-bit

slot and is set high for a 32-bit slot.

After initial software sequencing of the above signals is complete, the next step is to enable the CBT switches.

This can be done either by using the software to manually set the BUS_CTL bit or using the HPC3130A via the

automatic connection sequence mode located in the general configuration register.

HPC3130A

PCI HOT PLUG CONTROLLER

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connection sequencing (continued)

If automatic sequencing mode 1 is selected, then the BUS_CTL bit controls the sequencing by using idling

protocol. When this bit is set to zero, the switch–timing block will arbitrate for the PCI bus by asserting IDLEREQ.

Subsequently, IDLEGNT is asserted and the HPC3130A waits for bus idle condition. When FRAME and IRDY

are deasserted, the CBT switches are enabled. Following this, the SLOTRST, SLOTREQ64 and REQ64ON are

deasserted. Figure 7 depicts the sequencing of events when automatic sequencing mode 1 is enabled.

PCI_CLK

PWRON/OFF

PWRGOOD

SLOTRST

CLKON

REQ64ON

SLOTREQ64

BUS_CTL

IDLEREQ

IDLEGNT

FRAME

IRDY

BUSON

Figure 7. Automatic Connection Sequencing Mode 1

If automatic sequencing mode 2 is selected, then the BUS_CTL bit controls the sequencing by using idling

protocol. When this bit is set to zero, the switch timing block arbitrates for the PCI bus by asserting IDLEREQ.

Subsequently, IDLEGNT is asserted and the HPC3130A waits for the bus idle condition. When FRAME and

IRDY are deasserted, the SLOTRST is deasserted. Following this, the SLOTREQ64 and REQ64ON are

deasserted and the CBT switches are enabled. Figure 8 depicts the sequencing of events when automatic

sequencing mode 2 is enabled.

HPC3130A

PCI HOT PLUG CONTROLLER

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20 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

connection sequencing (continued)

PCI_CLK

PWRON/OFF

PWRGOOD

SLOTRST

CLKON

REQ64ON

SLOTREQ64

BUS_CTL

IDLEREQ

IDLEGNT

FRAME

IRDY

BUSON

Figure 8. Automatic Connection Sequencing Mode 2

The protocol described above is identical to the PCI REQ/GNT protocol used by PCI bus masters, which also

must wait for bus idle through PCI FRAME and IRDY before initiating a PCI cycle. If the HPC3130A is connected

to PCI FRAME and IRDY, the HPC3130A arbitrates for the bus; although it does not drive the PCI bus or assert

FRAME to start a cycle.

There are some issues with this implementation such as bus parking and additional loading on the PCI FRAME

and IRDY signals, which need to be considered when designing a system. The system designer may have a

level of confidence that PCI adapter cards can tolerate connection to a non-idle bus. In the scenario where the

HPC3130A is not connected to the bus, then the FRAME, IRDY, and IDLEGNT must be wired to valid logic levels

and the automatic sequencing will start without any relationship to the bus.

HPC3130A

PCI HOT PLUG CONTROLLER

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connection sequencing (continued)

IDLEREQ, IDLEGNT, FRAME, and IRDY pins are not connected in manual mode. In contrast, during automatic

connection, the HPC3130A requests the PCIBus to make sure it is idle before it sequences through the

connection sequence.

In manual mode, software has to perform each part of the connection sequence. Figure 9 is an example of the

manual connection sequence. There could be several other ways to implement this protocol.

PCI_CLK

PWRON/OFF

PWRGOOD

SLOTRST

CLKON

REQ64ON

SLOTREQ64

BUS_CTL

BUSON

Figure 9. Manual Connection Sequencing

disconnecting sequence

The HPC3130A provides two mechanisms to isolate a PCI slot from the PCI bus so an add–in card can be

removed. One of the mechanisms is called manual sequencing and is enabled by default. This mechanism

allows the software to control the entire disconnect sequence. This means it is the software’s responsibility to

remove a powered slot from the PCI bus without any impact to the system.

The second mechanism is called autosequencing and can be enabled by programming either Auto-Sequence

1 or Auto-Sequence 2 in the general configuration register

Unlike the connection sequence, which has two

different autoconnection sequencing modes, the autodisconnect sequence has only one mode of operation.

The steps in the autodisconnect sequence are as follows:

1. Software may assert SLOTRST to the appropriate slot by writing a 0 to the SLOTRST_O bit in the hot-plug

control register. This is optional.

2. Next the software must set the BUS_CTL bit in the hot-plug control register to a 1.

3. Once the BUS_CTL bit is set to a 1, the HPC3130A asserts IDLEREQ.

4. Once IDLEGNT is asserted and FRAME and IRDY are deasserted, the HPC3130A deasserts BUSON and

CLKON and asserts REQ64ON to isolate the slot from the PCI bus.

5. The HPC3130A then drives PWRON/OFF low to power off the slot.

HPC3130A

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disconnecting sequence (continued)

PCI_CLK

PWRON/OFF

PWRGOOD

SLOTRST

CLKON

REQ64ON

SLOTREQ64

BUS_CTL

IDLEREQ

IDLEGNT

FRAME

IRDY

BUSON

Figure 10. Automatic Disconnect Sequencing Mode

In manual disconnect mode, software has to perform each part of the disconnection sequence. Figure 11 is an

example of the manual disconnection sequence. There could be several other ways to implement this protocol.

During manual disconnection, the PCI bus may or may not idle; it will depend on the software implementation

of the system.

PCI_CLK

PWRON/OFF

PWRGOOD

SLOTRST

CLKON

REQ64ON

SLOTREQ64

BUS_CTL

BUSON

Figure 11. Manual Disconnect Sequencing Mode

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

64-bit implementation

When inserted into a slot, a 64-bit PCI card tests whether that slot is 64-bit or 32-bit. If REQ64 is low when

PCI_RST is deasserted, that signals the card that the slot is 64-bit; otherwise, the slot is 32-bit. The HPC3130A

provides a mechanism to notify the PCI card it is connected to a 64-bit PCI slot. The mechanism uses REQ64ON

and REQ64ON as CBT switch enables and SLOTREQ64 as the slot specific REQ64 signal. As depicted in

figures 12 and 13, REQ64ON enables the CBT switch that routes SLOTREQ64 to the slot, and REQ64ON

enables the CBT switch that routes SYSTEMREQ64 to the slot. SYSTEMREQ64 will always be routed to the

slot except when the slot is disconnected from the bus or during a connection sequence. It is very important

during a connection sequence that the software clears bit 3 in the

hot plug control register

to drive SLOTREQ64

low. The HPC3130A will deassert SLOTREQ64 during the automatic connection sequence.

In a 32-bit PCI bus implementation, the SLOTREQ64, REQ64ON, and REQ64ON outputs are not connected.

HPC_PCI

BUSON

System PCI Bus

REQ64ON

SYSTEMREQ64

REQ64ON

SLOTREQ64

CBT3306

PCI

SLOT

Figure 12. SLOTREQ64 Implementation Using CBT3306

HPC_PCI

BUSON

System PCI Bus

SYSTEMREQ64

REQ64ON

SLOTREQ64

CBT3257

S OE

PCI

SLOT

Figure 13. SLOTREQ64 Implementation Using CBT3257

HPC3130A

PCI HOT PLUG CONTROLLER

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24 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

66-MHz PCI support

The HPC3130A supports up to two slots in a 66-MHz system: slot 0 and slot 1. These hot-plug slot interfaces

include the M66EN signal and the SYSM66EN signal communicates hot-plug slot capability to the system.

Figure 14 illustrates the 66-MHz support function in the HPC3130A.

HPC–PCI M66EN FUNCTION

33 MHz

SYSM66EN

PCLK DRIVER

CB1G1257

PCI

SLOT

System PCI Bus

Motherboard

PCI Device

66 MHz

CLKON 0 PRST

M66EN_0

M66EN_I

Figure 14. HPC3130A 66-MHz System Support

When the PCIRST signal is deasserted, the SYSM66EN signal is latched and selects the system frequency.

Before an adapter card can be inserted, the slot is prepared for insertion by deasserting BUSON, deasserting

CLKON, and powering down the slot. When an adapter card is inserted into either hot-plug slot 0 or slot 1,

PWRON/OFF is high, and power is applied, the value M66EN from the card can be read through internal

registers. If the bus is operating at 66-MHz and a 33-MHz adapter card is inserted, then the software ensures

that the card is never connected to the bus. If the bus is operating at 33 MHz and a 66-MHz adapter card is

inserted, then the latched SYSM66EN state can be driven to the slot by enabling the CBT switch using CLKON.

SYSM66EN and CLKON input to a clock driver circuit to control the PCI clock frequency. The 66-MHz support

designed into the HPC3130A allows option cards to indicate PCI clock frequency capabilities upon PCI reset;

however, does not allow an inserted hot-plug card to alter the clock frequency of an operating PCI bus.

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

configuration and control registers

The HPC3130A register set is accessible through either a generic parallel bus interface or a two-wire serial

interface. Eight bytes of register space are provided per slot. Since the HPC3130A supports four slots, a total

of 32 bytes of registers is implemented. Register and bit descriptions are provided in the following sections and

indicate the bits that are common to all slots. The bit default values are given, which represent the state of the

HPC3130A after a PCI reset event. After a PCI reset, the HPC3130A drives outputs to a state such that the slots

appear as if they were not a hot-plug platform.

The register map that follows provides the register overview. Byte addressing is required when accessing the

internal registers. Read transactions from reserved registers return zeros.

Table 7. Register Map

SLOT REGISTER NAME ADDRESS SLOT REGISTER NAME ADDRESS

Slot 0 General configuration register 0x00 Slot 2 General configuration register 0x10

Slot 0 Hot-plug slot status register 0x01 Slot 2 Hot-plug slot status register 0x11

Slot 0 Hot-plug slot control register 0x02 Slot 2 Hot-plug slot control register 0x12

Slot 0 Attention indicator control 0x03 Slot 2 Attention indicator control 0x13

Slot 0 Reserved 0x04 Slot 2 Reserved 0x14

Slot 0 Reserved 0x05 Slot 2 Reserved 0x15

Slot 0 Interrupt event status register 0x06 Slot 2 Interrupt event status register 0x16

Slot 0 Interrupt event enable register 0x07 Slot 2 Interrupt event enable register 0x17

Slot 1 General configuration register 0x08 Slot 3 General configuration register 0x18

Slot 1 Hot-plug slot status register 0x09 Slot 3 Hot-plug slot status register 0x19

Slot 1 Hot-plug slot control register 0x0A Slot 3 Hot-plug slot control register 0x1A

Slot 1 Attention indicator control 0x0B Slot 3 Attention indicator control 0x1B

Slot 1 Reserved 0x0C Slot 3 Reserved 0x1C

Slot 1 Reserved 0x0D Slot 3 Reserved 0x1D

Slot 1 Interrupt event status register 0x0E Slot 3 Interrupt event status register 0x1E

Slot 1 Interrupt event enable register 0x0F Slot 3 Interrupt event enable register 0x1F

HPC3130A

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configuration and control registers (continued)

general configuration register

Bit 76543210

Name General configuration register

Type R R R R R/W R/W R R/W

Default 0 0 1 1 0 0 X 0

Type: Read-only, Read/Write

Offset: 00h (slot 0), 08h (slot 1), 10h (slot 2), 18h (slot 3)

Default: 0Xh

Description: This register is for general configurations and indications. The automatic PCI bus

connection sequencing is enabled through this register, and the register access mode is

indicated. This register is shared among all four slots.

Table 8. General Configuration Register

BIT TYPE NAME FUNCTION

7–4 R RSVD Reserved for revision ID. These bits return 0011b for this device.

3–2 R/W SEQUENCING

Automatic PCI bus connection sequencing. These bits control the sequencing used to connect the hot-

plug slot to the PCI bus.

00 = Manual sequencing through register accesses

01 = Auto–Sequence 1: Enable CBT switches before deasserting RST

10 = Auto–Sequence 2: Enable CBT switches after deasserting RST

11 = Reserved

1 R SYSM66STAT

Status of SYSM66EN. This bit represents the latched value of SYSM66EN during a PCI reset. A value of

1 indicates the PCI bus is operating at a frequency greater than 33 MHz. A value of 0 indicates the PCI

bus is operating at 33 MHz or less.

0 R/W PROTECTEN

Protection enable. This bit enables a protection mechanism provided by the HPC3130A. When this bit is

enabled and either of the DETECT[1:0] inputs are high, the HPC3130A drives the BUS_ON and CLKON

outputs high. The HPC3130A also drives PWRON/OFF and REQ64ON outputs low.

HPC3130A

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configuration and control registers (continued)

hot-plug slot status register

Bit 7 6 5 4 3 2 1 0

Name Hot-plug slot status register

Type R R R R R R R R

Default XXXXXXXX

Type: Read-only

Offset: 01h (slot 0), 09h (slot 1), 11h (slot 2), 19h (slot 3)

Default: XXh

Description: This register reports card detection, power status, and other chip input from the hot-plug

slot interface. All bits in this register are read only, and the data read from each bit

represents the logical value of the data input from the corresponding terminal.

Table 9. Hot-Plug Slot Status Register

BIT TYPE NAME FUNCTION

7 R BUSON Bus on. This bit returns the logical value of the BUSON terminal output.

6 R M66EN_I M66EN input. This bit returns the logical value of the M66EN terminal input.

5 R PWRGOOD_I Power good input. This bit returns the logical value of the PWRGOOD terminal input.

4 R PWRFAULT_I Power fault input. This bit returns the logical value of the PWRFAULT terminal input.

3 R DETECT1_I Mech detect 1 input. This bit returns the logical value of the DETECT1 terminal input.

2 R DETECT0_I Mech detect 0 input. This bit returns the logical value of the DETECT0 terminal input.

1 R PRSNT2_I Card present 2 input. This bit returns the logical value of the PRSNT2 terminal input.

0 R PRSNT1_I Card present 1 input. This bit returns the logical value of the PRSNT1 terminal input.

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configuration and control registers (continued)

hot-plug slot control register

Bit 76543210

Name Hot-plug slot control register

Type R R R/W R/W R/W R/W R/W R/W

Default 00101101

Type: Read-only, Read/Write

Offset: 02 (slot 0), 0Ah (slot 1), 12h (slot 2), 1Ah (slot 3)

Default: 2Dh

Description: This register applies power, resets, and provides general control of a hot-plug slot

connection to the system PCI bus.

Table 10. Hot-Plug Slot Control Register

BIT TYPE NAME FUNCTION

7 R RSVD Reserved. This bit returns 0 when read.

6 R RSVD Reserved. This bit returns 0 when read.

5 R/W SLTPWR_CTL

Slot power On/Off control. The data written to this bit represents the logical value of the data to drive the

PWRON/OFF output and is used to control the power state of a hot-plug slot. If the PROTECTEN bit in the

general configuration register is set to 1, then a logic high can only be driven by the PWRON/OFF output if

the DETECT[1:0] inputs are low.

4 R/W BUS_CTL

PCI bus CBT-switch control. When manual sequencing is enabled, then the value written to this bit

represents the logical value of the data driven to the BUSON output, and it is used to connect/disconnect a

hot-plug slot to/from the PCI bus.

If an auto sequencing mode is enabled in the general configuration register, then this bit functions as follows:

1 = By setting this bit, the hot-plug slot gets disconnected from the PCI bus. This is accomplished by

asserting IDLEREQ, then waiting for IDLEGNT assertion and deassertion of FRAME and IRDY

before driving BUSON high, CLKON high, REQ64ON low, and PWRON/OFF low.

0 = By clearing this bit, the hot-plug slot gets connected to the PCI bus. This is accomplished by asserting

IDLEREQ, then waiting for IDLEGNT assertion and deassertion of FRAME and IRDY before driving

BUSON low. Also verifies assertion of DETECT[1:0] if the protection enable bit is enabled in the

general configuration register.

3 R/W SLOTREQ64

Slot request 64-bit control. The data written to this bit represents the logical value of the data driven to the

SLOTREQ64 output and is used during reset of a slot after power is applied. This input indicates to an option

card whether or not it is connected to a 64-bit slot.

2 R/W REQ64_O REQ64 CBT switch control. The data written to this bit represents the logical value of the data driven to the

REQ64ON output and is used to control the CBT switch that implements the REQ64 PCI signal.

1 R/W CLKON_O CLKON CBT switch control. The data written to this bit represents the logical value of the data driven to the

CLKON output and is used to control the clock driver to the hot-plug slot.

0 R/W SLOTRST_O Slot reset control. The data written to this bit represents the logical value of the data driven to the SLOTRST

output and is used to reset a hot-plug slot after power is applied.

HPC3130A

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configuration and control registers (continued)

attention indicator control register

Bit 7 6 5 4 3 2 1 0

Name Attention indicator control register

Type R R R R R/W R/W R/W R/W

Default 0 0 0 0 0 0 0 0

Type: Read-only, Read/Write

Offset: 03 (slot 0), 0Bh (slot 1), 13h (slot 2), 1Bh (slot 3)

Default: 00h

Description: This register controls the attention indicators. The timing for the indicators is based upon

the PCI clock and the M66EN input.

Table 11. Attention Indicator Control Register

BIT TYPE NAME FUNCTION

7 R RSVD Reserved. This bit returns 0 when read.

6 R RSVD Reserved. This bit returns 0 when read.

5 R RSVD Reserved. This bit returns 0 when read.

4 R RSVD Reserved. This bit returns 0 when read.

3–2 R/W ATTN1_CTL

Attention indicator 1 control. These bits control the state of ATTN1 per slot and are programmed as follows:

00 = Drive low

01 = Slow blink – 1 cycle per second

10 = Fast blink – 2 cycles per second

11 = Drive high

1–0 R/W ATTN0_CTL

Attention indicator 0 control. These bits control the state of ATTN0 per slot and are programmed as follows:

00 = Drive low

01 = Slow blink – 1 cycle per second

10 = Fast blink – 2 cycles per second

11 = Drive high

HPC3130A

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configuration and control registers (continued)

interrupt event status register

Bit 76543210

Name Interrupt event status register

Type R R/C R/C R/C R/C R/C R/C R/C

Default 00000000

Type: Read-only, Read/Clear

Offset: 06h (slot 0), 0Eh (slot 1), 16h (slot 2), 1Eh (slot 3)

Default: 00h

Description: This register reads interrupt status, and clears the interrupt. All functional bits in this

to generate an interrupt, signaled through the open-drain INTR, after detecting various

events. Each event is individually enabled through the interrupt event enable register.

Table 12. Interrupt Event Status Register

BIT TYPE NAME FUNCTION

7 R RSVD Reserved. This bit returns 0 when read.

6 R/C BUS_S PCI Bus CBT switch status. This bit is set when the BUSON output changes state, and is cleared by a

write back of 1. The BUS event is intended for use with the idling protocol.

5 R/C PWRGOOD_S Power good status. This bit is set when the PWRGOOD input changes state.

4 R/C PWRFAULT_S Power fault status. This bit is set when the PWRFAULT input is asserted.

3 R/C DETECT1_S Mechanical detect 1 status. This bit is set when the DETECT1 input changes state.

2 R/C DETECT0_S Mechanical detect 0 status. This bit is set when the DETECT0 input changes state.

1 R/C PRSNT2_S Card present 2 status. This bit is set when the PRSNT2 input changes state.

0 R/C PRSNT1_S Card present 1 status. This bit is set when the PRSNT1 input changes state.

HPC3130A

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configuration and control registers (continued)

interrupt event enable register

Bit 7 6 5 4 3 2 1 0

Name Interrupt event enable register

Type R R/W R/W R/W R/W R/W R/W R/W

Default 0 0 0 0 0 0 0 0

Type: Read-only, Read/Write

Offset: 07h (slot 0), 0Fh (slot 1), 17h (slot 2), 1Fh (slot 3)

Default: 00h

Description: This register is used to enable interrupts, signaled through the open-drain INTR, after

detecting various events. Event status is reported through the interrupt event status

Table 13. Interrupt Event Enable Register

BIT TYPE NAME FUNCTION

7 R RSVD Reserved. This bit returns 0 when read.

6 R/W BUS_E PCI bus CBT switch event enable. When this bit is set, an INTR is signaled when the BUSON output

changes state. The BUS event is intended for use with the idling protocol.

5 R/W PWRGOOD_E Power good event enable. When this bit is set, an INTR is signaled when the PWRGOOD input changes

state.

4 R/W PWRFAULT_E Power fault event enable. When this bit is set, an INTR is signaled when PWRFAULT input is asserted.

3 R/W DETECT1_E Mechanical detect 1 event enable. Enables INTR events on DETECT1 input state changes.

2 R/W DETECT0_E Mechanical detect 0 event enable. Enables INTR events on DETECT0 input state changes.

1 R/W PRSNT2_E Card present 2 event enable. Enables INTR events on PRSNT2 input state changes.

0 R/W PRSNT1_E Card present 1 event enable. Enables INTR events on PRSNT1 input state changes.

HPC3130A

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absolute maximum ratings over operating free-air temperature range†

Supply voltage range, VCC –0.5 V to 3.6 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

VCCP and VCC5V –0.5 V to 5.5 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Input voltage range, VI: PCI –0.5 V to VCCP + 0.5 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

SLOT –0.5 V to VCC5V + 0.5 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

BUSON –0.5 V to VCC5V + 0.5 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Parallel –0.5 V to VCC5V + 0.5 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Parallel/serial –0.5 V to VCC5V + 0.5 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Miscellaneous –0.5 V to VCC5V + 0.5 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Output voltage range, VO: PCI –0.5 V to VCCP + 0.5 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

SLOT –0.5 V to VCC5V + 0.5 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

BUSON –0.5 V to VCC5V + 0.5 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Parallel –0.5 V to VCC5V + 0.5 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Parallel/serial –0.5 V to VCC5V + 0.5 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Miscellaneous –0.5 V to VCC5V + 0.5 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Input clamp current, IIK (VI< 0 or VI > VCC) (see Note 1) ±20 mA. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Output clamp current, IOK (VO < 0 or VO > VCC) (see Note 2) ±20 mA. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Storage temperature range –65_C to 150_C. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Junction temperature, TJ150_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.

NOTES: 1. Applies to external input and bidirectional buffers. For 5-V tolerant use VI > VCC5V. For universal PCI, use VI > VCCP

2. Applies to external output and bidirectional buffers. For 5-V tolerant use VO > VCC5V. For universal PCI, use VO > VCCP

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

recommended operating conditions

MIN NOM MAX UNIT

VCC Core voltage Commercial 3 3.3 3.6 V

VCCP PCI I/O voltage Commercial 3 5 5.5 V

VCC5V Slot I/O voltage Commercial 3 5 5.5 V

VCC5V Parallel I/O voltage Commercial 3 5 5.5 V

VCC5V Serial I/O voltage Commercial 3 5 5.5 V

VCC5V Miscellaneous I/O voltage Commercial 3 5 5.5 V

PCI 0 VCCP

Slot 0 VCC5V

Input voltage

BUSON 0 VCC5V

VIInput voltage Parallel 0 VCC5V

Parallel/Serial 0 VCC5V

Miscellaneous 0 VCC5V

PCI 0 VCC

Slot 0 VCC

Output voltage†

BUSON 0 VCC

VOOutput voltage

†

Parallel 0 VCC

Parallel/Serial 0 VCC

Miscellaneous 0 VCC

PCI 2 VCCP

Slot 2 VCC5V

High level input voltage

BUSON 2 VCC5V

VIH High-level input voltage Parallel 2 VCC5V

Parallel/Serial 2 VCC5V

Miscellaneous 2 VCC5V

PCI 0 0.8

Slot 0 0.8

Low level input voltage

BUSON 0 0.8

VII Low-level input voltage Parallel 0 0.8 V

Parallel/Serial 0 0.8

Miscellaneous 0 0.8

PCI 0 6

Slot 0 6

ttInput transition time (tr and tf) (10% to 90%) BUSON 0 6 ns

In ut transition time (trand tf) (10% to 90%)

Parallel/Serial 0 6

Miscellaneous 0 6

TAOperating ambient temperature range 0 25 70 °C

TJVirtual junction temperature‡0 25 115 °C

†Applies to external output buffers.

‡These junction temperatures reflect simulation conditions. Customer is responsible for verifying junction temperature.

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

34 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

serial bus interface

STANDARD MODE FAST MODE

UNIT

MIN MAX MIN MAX UNIT

VIL Low-level input voltage Fixed:

VCC5V related:

–0.5

1.5

0.3 VCC5V

–0.5

1.5

0.3 VCC5V V

VIH High-level input voltage Fixed:

VCC5V related:

0.7 VCC5V

VCC5V max + 0.5

0.7 VCC5V

VCC5V max + 0.5

VCC5V max + 0.5 V

electrical characteristics over recommended operating conditions

PARAMETER PINS OPERATION TEST CONDITIONS MIN MAX UNIT

PCIh

3.3 V IOH = –0.5 mA 0.9 VCC

PCIh5 V IOH = –2 mA VCC – 0.6

Slot§IOH = –8mA VCC – 0.6

VOH High-level output voltage BUSON¶IOH = –8mA VCC – 0.6 V

VOH

High level out ut voltage

Parallel#IOH = –4mA VCC – 0.6

Parallel/Serial|| IOH = –4mA VCC – 0.6

MiscellaneouskIOH = –8mA VCC – 0.6

PCIh

3.3 V IOL = 1.5 mA 0.1 VCC

PCIh5 V IOL = 6 mA 0.55

Slot§IOL = 8mA 0.5

VOL Low-level output voltage BUSON¶IOL = 8mA 0.5 V

VOL

Low level out ut voltage

Parallel#IOL = 4mA 0.5

Parallel/Serial|| IOL = 4mA 0.5

MiscellaneouskIOL = 2mA 0.5

PCIhVI = GND –20

Slot§VI = GND –20

I†

Low level input current‡

BUSON¶VI = GND –20

IIL

†

Low-level input current

‡

Parallel#VI = GND –20 µA

Parallel/Serial|| VI = GND –20

MiscellaneouskVI = GND –20

PCIhVI = VCC 20

Slot§VI = VCC 20

I†

High level input current‡

BUSON¶VI = VCC 20

IIH

†

High-level input current

‡

Parallel#VI = VCC 20 µA

Parallel/Serial|| VI = VCC 20

MiscellaneouskVI = VCC 20

IOZ High-impedance-state output

current VI = VCC or GND ±20 µA

†Specifications apply only when pullup terminator is turned off.

‡For I/O pins, the imput leakage current includes the off state output current IOZ.

hPCI terminals: 120 PBM — 12, 13, 14, 16, 18, 19, 20, 21, 23, 24, 25, 27. 128 PBK — 13, 14, 15, 17, 19, 20, 21, 22, 24, 25, 26, 28. 144 PGE —

15, 16, 17, 19, 21, 22, 23, 24, 26, 27, 28, 30.

§Slot terminals: 120 PBM — 7, 8, 9, 10, 58, 77, 97, 115. 128 PBK — 8, 9, 10, 11, 61, 82, 104, 122. 144 PGE — 10, 11, 12, 13, 68, 92, 118, 136.

¶BUSON terminals: 120 PBM — 63, 81, 100, 119. 128 PBK — 68, 86, 107, 126. 144 PGE — 77, 96, 121, 142

#Parallel terminals: 120 PBM — 35, 37, 38, 39, 40, 42. 128 PBK — 38, 40, 41, 42, 43, 45. 144 PGE — 44, 46, 47, 48, 49, 51

|| Parallel/serial terminals: 120 PBM — 43, 44, 45, 47, 48, 49, 50. 128 PBK — 46, 47, 48, 50, 51, 52, 53. 144 PGE — 52, 53, 54, 56, 57, 58, 59.

kMiscellaneous terminals: All terminals other than PCI, slot, BUSON, parallel, and parallel/serial.

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

PCI clock/reset timing requirements over recommended ranges of supply voltage and operating

free-air temperature

PARAMETER ALTERNATE

SYMBOL TEST CONDITIONS MIN MAX UNITS

tcPCLK cycle time tcyc 15 ns

twH PCLK high time thigh 6 ns

twL PCLK low time tlow 6 ns

dv/dt PCLK slew rate tr, tf 1.5 4 V/ns

twRSTIN pulse width trst 1 ms

tsu PCLK active time at end of RSTIN trst–clk 100 ms

Pin definitions for 120-pin PBM package

PARAMETER PIN NUMBER

PCI 14, 16, 18, 19, 20, 21, 25, 27

Slot

1, 2, 3, 4, 5, 7, 8, 9, 10, 52, 53, 54, 55, 57, 58, 59, 60, 64, 65, 66, 67, 69,

70, 71, 72, 73, 75, 76, 77, 78, 80, 82, 83, 84, 86, 87, 88, 91, 92, 93, 94,

96, 97, 98, 99, 102, 103, 104, 105, 106, 108, 109, 110, 111, 113, 114,

115, 116, 118, 120

BUSON 63, 81, 100, 119

Parallel 34, 35, 37, 38, 39, 40, 42

Parallel/serial 23, 24, 29, 30, 43, 44, 45, 47, 48, 49, 50

Miscellaneous 12, 13

Pin definitions for 128-pin PBK package

PARAMETER PIN NUMBER

PCI 15, 17, 19, 20, 21, 22, 26, 28,

Slot

2, 3, 4, 5, 6, 8, 9, 10, 11, 55, 56, 57, 58, 60, 61, 62, 63, 69, 70, 71, 72,

74, 75, 76, 77, 78, 80, 81, 82, 83, 85, 87, 88, 89, 91, 92, 93, 98, 99, 100,

101, 103, 104, 105, 106, 109, 110, 111, 112, 113, 115, 116, 117, 118,

120, 121, 122, 123, 125, 127

BUSON 68, 86, 107, 126

Parallel 37, 38, 40, 41, 42, 43, 45,

Parallel/serial 24, 25, 30, 31, 46, 47, 48, 50, 51, 52, 53

Miscellaneous 13, 14

Pin definitions for 144-pin PGE package

PARAMETER PIN NUMBER

PCI 17, 19, 21, 22, 23, 24, 28, 30

Slot

1, 3, 5, 7, 8, 10, 11, 12, 13, 61, 62, 63, 64, 66, 68, 70, 72, 79, 80, 81, 82,

84, 85, 86, 87, 88, 90, 91, 92, 93, 95, 97, 98, 99, 101, 102, 104, 109,

111, 113, 115, 117, 118, 119, 120, 123, 124, 125, 126, 127, 129, 130,

131, 132, 134, 135, 136, 137, 140, 144

BUSON 77, 96, 121, 142

Parallel 43, 44, 46, 47, 48, 49, 51

Parallel/serial 26, 27, 34, 36, 52, 53, 54, 56, 57, 58, 59

Miscellaneous 15, 16

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

36 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

PCI timing requirements over recommended ranges of supply voltage and operating free–air

temperature†(see Note 3)

PARAMETER ALTERNATE

SYMBOL TEST CONDITIONS MIN MAX UNITS

tpd Propagation delay time PCLK to shared signal valid delay

time tval

CL = 50 pF,

See Note 4,

1,2,3

211 ns

ten Enable time, high-impedance-to-active delay time from PCLK ton 2 ns

tdis Disable time, active-to-high-impedance delay time from PCLK toff 28 ns

tsu Valid setup time, before PCLK tsu 3,4 3 ns

thHold time, after PCLK high th4 0 ns

†Applies to external output buffers.

NOTES: 3. This data sheet uses the following conventions to describe time ( t ) intervals. The format is: tA, where subscript A indicates the type

of dynamic parameter being represented. One of the following is used: tpd = propagation delay time, td = delay time, tsu = setup time,

and th = hold time.

4. PCI shared signals are AD31–AD0, C/BE3–C/BE0, PCIFRAME, PCITRDY, PCIIRDY, PCISTOP, IDSEL, PCIDEVSEL, and

PCIPAR.

serial bus interface†

STANDARD

MODE FAST MODE UNIT

MIN MAX MIN MAX

UNIT

fSCL SCL clock frequency (see Note 5) 0 100 0 400 kHz

tBUF Bus free time between a STOP and START condition 4.7 1.3 µs

tHD;STA Hold time (repeated) START condition. After this period, the first clock pulse is

generated. 4 0.6 µs

tLOW LOW period of the SCL clock 4.7 1.3 µs

tHIGH HIGH period of the SCL clock 4 0.6 µs

tSU;STA Setup time for a repeated START condition 4.7 0.6 µs

Data hold time (see Note 6)

For CBUS compatible masters: 5

tHD;DAT Data hold time (see Note 6) For serial bus devices: 01010.92

µs

tSU;DAT Data setup time (see Note 7) 250 1003µs

tRRise time of both SDA and SCL signals 1000 20 300 µs

tFFall time of both SDA and SCL signals 300 20 300 µs

tFSU;STO Setup time for STOP condition 4 0.6 µs

†All values refer to serial bus interface VIH MIN and VIL MAX levels

NOTES: 5. A device must internally provide a hold time of at least 300 ns for the SDA signal (referred to the VIH MIN of the SCL signal) in order

to bridge the undefined region of the falling edge of SCL.

6. The maximum tHD;DAT has only to be met if the device does not stretch the LOW period (tLOW ) of the SDL signal.

7. A fast mode serial bus device can be used in a standard mode serial bus system, but the requirement tSU;DAT > 250 ns must then

be met. This will automatically be the case if the device does not stretch the LOW period of the SCL signal. If such a device does

stretch the LOW period of the SCL signal, it must output the next data bit to the SDA line tR MAX + tSU;DAT = 1000 + 250 = 1250 ns

(according to the

Standard Mode Serial Bus Specification

) before the SCL line is released.

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

MECHANICAL DATA

PBM (S-PQFP-G***) PLASTIC QUAD FLATPACK

4040023/ D 06/96

0,16 NOM

0,45

0,30

Gage Plane

0,25

1,03

0,73

0,25 MIN

Seating Plane

120

31,45

30,95

28,20

27,80

3,60

3,20

4,10 MAX

0,20

0,80

0,10

0°–ā7°

120-PIN SHOWN

120QFP

NO. OF

PINS***

23,20 TYP

NOTES: A. All linear dimensions are in millimeters.

B. This drawing is subject to change without notice.

C. Falls within JEDEC MS-022

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

38 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

MECHANICAL DATA

PBK (S-PQFP-G128) PLASTIC QUAD FLATPACK

128-PIN SHOWN

4040279-3/ C 11/96

Gage Plane

0,13 NOM

0,25

0,45

0,75

Seating Plane

0,05 MIN

0,23

12,40 TYP

0,13

128

13,80

16,20

15,80

1,60 MAX

1,45

1,35

14,20

0°–ā7°

0,08

0,40 M

0,07

NO. OF

PINS*** A

128 LQFP 24,80 TYP

NOTES: A. All linear dimensions are in millimeters.

B. This drawing is subject to change without notice.

C. Falls within JEDEC MS-026

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

MECHANICAL DATA

PGE (S-PQFP-G144) PLASTIC QUAD FLATPACK

144-PIN SHOWN

4040147/ C 11/96

0,27

0,17

0,13 NOM

0,25

0,75

0,45

0,05 MIN

Seating Plane

Gage Plane

108

109

144

22,20

21,80

19,80

17,50 TYP

20,20

1,35

1,45

1,60 MAX

0,08

0°–ā7°

0,08

0,50

NOTES: A. All linear dimensions are in millimeters.

B. This drawing is subject to change without notice.

C. Falls within JEDEC MS-026

HPC3130A

PCI HOT PLUG CONTROLLER

SCPS055 – NOVEMBER 1999

40 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

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

DEATH, PERSONAL INJURY, OR SEVERE PROPERTY OR ENVIRONMENTAL DAMAGE (“CRITICAL

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PACKAGING INFORMATION

Orderable Device Status (1) Package

Type

Package

Drawing

Pins Package

Qty

Eco Plan (2) Lead/Ball Finish MSL Peak Temp (3)

HPC3130APBK ACTIVE LQFP PBK 128 90 TBD CU NIPDAU Level-4-220C-72 HR

HPC3130APBM ACTIVE QFP PBM 120 24 TBD Call TI Level-3-220C-168 HR

HPC3130APGE ACTIVE LQFP PGE 144 60 Green (RoHS &

no Sb/Br)

CU NIPDAU Level-2-260C-1 YEAR

(1) The marketing status values are defined as follows:

ACTIVE: Product device recommended for new designs.

LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.

NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in

a new design.

PREVIEW: Device has been announced but is not in production. Samples may or may not be available.

OBSOLETE: TI has discontinued the production of the device.

(2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS) or Green (RoHS & no Sb/Br) - please check

http://www.ti.com/productcontent for the latest availability information and additional product content details.

TBD: The Pb-Free/Green conversion plan has not been defined.

Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements

for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered

at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.

Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame

retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material)

(3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder

temperature.

Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is

provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the

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incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited

information may not be available for release.

In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI

to Customer on an annual basis.

PACKAGE OPTION ADDENDUM

www.ti.com 19-Sep-2005

Addendum-Page 1

IMPORTANT NOTICE

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and conditions of sale supplied at the time of order acknowledgment.

TI warrants performance of its hardware products to the specifications applicable at the time of sale in

accordance with TI’s standard warranty. Testing and other quality control techniques are used to the extent TI

deems necessary to support this warranty. Except where mandated by government requirements, testing of all

parameters of each product is not necessarily performed.

TI assumes no liability for applications assistance or customer product design. Customers are responsible for

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