TI TSB14C01APM

TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
D
D
D
D
D
D
Supports Provisions of IEEE 1394-1995
(1394) Standard for High-Performance
Serial Bus†
Fully Interoperable With FireWire
Implementation of 1394
Provides A Backplane Environment That
Supports 50 or 100 Megabits per Second
(Mbits/s)
Logic Performs System Initialization and
Arbitration Functions
Encode and Decode Functions Included for
Data-Strobe Bit-Level Encoding
Incoming Data Resynchronized to Local
Clock
D
D
D
D
D
D
Separate Transmitter and Receiver for
Greater Flexibility
Data Interface to Link-Layer Controller
(Link) Provided Through Two Parallel
Signal Lines at 25/50 MHz
100-MHz or 50-MHz Oscillator Provides
Transmit, Receive-Data, and Link Clocks at
25/50 MHz
Single 5-V Supply Operation
Packaged in a High-Performance 64-Pin
TQFP (PM) Package for 0°C to 70°C
Operation and – 40°C to 85°C Operation
Packaged in a 68-Pin CFP (HV) Package for
– 55°C to 125°C Operation
description
The TSB14C01A provides the transceiver functions needed to implement a single port node in a backplanebased 1394 network. The TSB14C01A provides two terminals for transmitting, two terminals for receiving, and
a single terminal to externally control the drivers for data and strobe. The TSB14C01A is not designed to drive
the backplane directly, this function must be provided externally. The TSB14C01A is designed to interface with
a link-layer controller (link), such as the TSB12C01A.
The TSB14C01A requires an external 98.304-MHz or 49.152-MHz reference oscillator input for S100/50
operation. The reference signal is internally divided to provide the 49.152-MHz ±100-ppm system clock signals
used to control transmission of the outbound encoded strobe and data information. The 49.152-MHz clock
signal is supplied to the associated link for synchronization of the two chips. When this device is in the S100
mode of operation, OSC_SEL is asserted high. When the TSB14C01A is in the S50 mode of operation, the clock
rate supplied to the link is 24.576 MHz.
Data bits to be transmitted are received from the link on two parallel paths and are latched internally in the
TSB14C01A in synchronization with the 49.152-MHz system clock. These bits are combined serially, encoded,
and then transmitted at 98.304-Mbits/s (in S100 mode) as the outbound data-strobe information stream. During
transmission, the encoded data information is transmitted on TDATA, and the encoded strobe information is
transmitted on TSTRB.
During packet reception the encoded information is received on RDATA and strobe information on RSTRB. The
received data-strobe information is decoded to recover the receive clock signal and the serial data bits. The
serial data bits are split into two parallel streams, resynchronized to the local system clock, and sent to the
associated link.
The TSB14C01A is a 5-V device and provides CMOS-level outputs.
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.
† This serial bus implements technology covered by one or more patents of Apple Computer, Incorporated and SGS Thomson, Limited.
FireWire is a trademark of Apple Computer, Incorporated.
Copyright  1999, 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.
On products compliant to MIL-PRF-38535, all parameters are tested
unless otherwise noted. On all other products, production
processing does not necessarily include testing of all parameters.
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
1
TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
AVAILABLE OPTIONS
PACKAGES
TA
CERAMIC FLAT PACK
(HV)
THIN QUAD FLAT PACK
(PM)
0°C to 70°C
—
TSB14C01APM
– 40°C to 85°C
—
TSB14C01AIPM
– 55°C to 125°C
TSB14C01AMHV
—
1
64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49
48
2
47
3
46
4
45
5
44
6
43
7
42
8
TSB14C01A
9
41
40
10
39
11
38
12
37
13
36
14
35
15
34
33
16
1718 19 20 21 22 23 24 25 26 27 28 29 30 31 32
VCC
EN_EXID
EN_EXPRI
EX_ID5
EX_ID4
EX_ID3
EX_ID2
EX_ID1
EX_ID0
GND
EX_PRI3
EX_PRI2
EX_PRI1
EX_PRI0
NC
NC
ARB_CLK
PHYENA
VCC
ENA_PRI
VCC
N_POR
GND
LREQ
VCC
SCLK
TSCLK
GND
CTL0
CTL1
D0
D1
OSC_SEL
GND
GND
RPREFIX
VCC
VCC
GND
VCC
TI1
VCC
NC
XI_50
GND
NC
XI_100
GND
PM PACKAGE
(TOP VIEW)
NC – No connection
2
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
NC
NC
NC
NC
NC
RDATA
RSTRB
VCC
TDATA
TSTRB
GND
N_OEB_D
GND
PTEST_INDRV
VCC
NC
TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
NC
GND
RPREFIX
VCC
VCC
GND
VCC
TI1
VCC
NC
XI_50
GND
NC
XI_100
GND
OSC_SEL
GND
HV PACKAGE
(TOP VIEW)
9
10
8 7
6
5 4 3 2
1 68 67 66 65 64 63 62 61
60
11
59
12
58
13
57
14
56
15
55
16
54
17
18
53
TSB14C01AM
52
19
51
20
50
21
49
22
48
23
47
24
46
25
NC
NC
NC
NC
NC
RDATA
RSTRB
VCC
TDATA
TSTRB
GND
N_OEB_D
GND
PTEST_INDRV
VCC
NC
NC
VCC
EN_EXID
EN_EXPRI
EX_ID5
EX_ID4
EX_ID3
EX_ID2
EX_ID1
EX_ID0
GND
EX_PRI3
EX_PRI2
EX_PRI1
EX_PRI0
NC
45
26
44
27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43
NC
NC
NC
ARB_CLK
PHYENA
VCC
ENA_PRI
VCC
N_POR
GND
LREQ
VCC
SCLK
TSCLK
GND
CTL0
CTL1
D0
D1
NC – No connection
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
3
TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
system block diagram
N_OEB_D
D0 – D1
1394 LinkLayer
Controller
Host
Interface
2
/
CTL0 – CTL1
TSB14C01A
Tdata
1394
Backplane
PhysicalLayer
Controller
Rdata
BPdata
2
/
LREQ
BPstrb
Tstrb
Rstrb
SCLK
NOTE A: The backplane transceiver is customer supplied and is different for each type of backplane.
functional block diagram
SCLK
D0, D1
Data
Encode
SCLK
TxPktStrb
CLK
Physical ID
TxPktData
Pr0 – Pr3
2
D0 – D1
/
/
Arb Won
LINK/PHY
Interface
TxArbData
Arb Lost
ARB
Control
Arb Res Gap
Sub Act Gap
Ack Gap
RxStb
RxData
Bus Reset
CLK
CLK
RSTRB
RDATA
Data
Resync/
Decode
RxData
RxCLK
RxCLK
NOTE A: CLK is either terminal XI_50 or XI_100 depending on the mode selection.
4
TDATA
Ack Req
LREQ
CLK
(see Note A)
TSTRB
TxArbStrb
Iso Req
Cycle Req
2
CTL0 – CTL1
ARB/DATA
MUX
Fair/Urg Req
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
Terminal Functions
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PM
NO.
HV
NO.
TYPE
I/O
1
11
TTL
O
Arbitration clock. ARB_CLK is the clock used for arbitration. ARB_CLK is
for test and debug. It can be put into a high-impedance state by
PTEST_INDRV. This terminal is not used in normal operation and is
always at 49.152 MHz.
CTL0, CTL1
13, 14
23, 24
TTL
I/O
Control I/O. These are bidirectional signals that communicate between the
TSB14C01A and the link that controls passage of information between the
two devices.
D0, D1
15, 16
25, 26
TTL
I/O
Data I/O. These are bidirectional information signals that communicate
between the TSB14C01A and the link layer.
ENA_PRI
4
14
TTL
I
Enable priority. ENA_PRI is tied low to enable the 7-bit bus request. See
Table 1 for more information.
EN_EXID
18
30
TTL
I
Enable external ID. When EN_EXID is asserted high, the ID for this node
is set externally by EX_ID. When this terminal is tied/driven low, the
source of the ID comes from the internal ID register.
EN_EXPRI
19
31
TTL
I
Enable external priority. When EN_EXPRI is asserted high (external
priority enabled) the priority level for this node is set externally (see
Table 1). This terminal should be tied low when not used.
20,21,22,
23,24,25
32,33,34,
35,36,37
TTL
I
External ID. The ID for this node is determined by the value on the EX_ID
terminals. Bit 0 is the MSB.
27,28,
29,30
39,40,
41,42
TTL
I
External priority. The priority for this node is determined by the values on
the EX_PRI terminals. See Table 1 for more information.
GND
7,12,26,
36,38,49,
51,54,60,
64
4,8,17,
22,38,48,
50,61,63,
66
Supply
—
LREQ
8
18
TTL
I
VCC
3,5,9,17,
34,41,57,
59,61,62
1,3,5,6,
13,15,19,
29,46,53
Supply
—
Circuit power
NC
31,32,33,
44,45,46,
47,48,53,
56
9,10,27,
28,43–45,
56–60,
65,68
—
—
Not connected. These terminals must be left floating.
N_OEB_D
37
49
TTL
O
External driver enable. N_OEB_D is a negative active signal that enables
the external driver for TDATA and TSTRB.
N_POR
6
16
TTL
I
Logic reset input . Forcing N_POR low causes a reset condition and
resets the internal logic to the reset start state.
OSC_SEL
50
62
VCC /
GND
I
Select clock frequency. OSC_SEL should be pulled up to VCC when the
operating frequency is 50 MHz. When the operating frequency is 100 MHz
then it should be pulled to ground. It should not be left floating.
PHYENA
2
12
TTL
O
Phy enable. When the phy is driving it is low, PHYENA is the control to the
CTL0, CTL1, D0, and D1 drivers. PHYENA is for test and debug. It can
be put into a high-impedance state by PTEST_INDRV. This terminal is not
used in normal operation.
PTEST_INDRV
35
47
TTL
I
RDATA
43
55
TTL
I
Test output enable. PTEST_INDRV enables/disables the drivers to the
test terminals ARB_CLK, PHYENA, and RPREFIX. During normal
operation, PTEST_INDRV should be tied to VCC to disable the drivers.
Receive data. Incoming data is received at the data rate.
NAME
ARB_CLK
EX_ID5 – EX_ID0
EX_PRI3 –
EX_PRI0
DESCRIPTION
Circuit ground
Link request input. LREQ is an input from the link used by the link to
signal the TSB14C01A of a request to perform some service.
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
5
TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
Terminal Functions (continued)
TERMINAL
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PM
NO.
HV
NO.
TYPE
I/O
RPREFIX
63
7
TTL
O
Receiver prefix. When asserted high (enabled), RPREFIX alerts the
receiver of an incoming packet. RPREFIX is for test and debug and is not
used in normal operation.
RSTRB
42
54
TTL
I
Receive strobe. RSTRB decodes the received data.
SCLK
10
20
TTL
O
System clock output. A 49.152-MHz or 24.576-MHz clock signal
synchronized with the data transfers, and provided to the link.
TDATA
40
52
CMOS
O
Transmit data. Data to be transmitted is serialized on TDATA.
TI1
58
2
TTL
I
Test input 1. TI1 is used for test purposes only and should be tied to
ground for normal operation.
TSCLK
11
21
TTL
O
System clock output. A 49.152-MHz or 24.576-MHz clock signal that is 180
degrees out of phase with SCLK; it is available if needed.
TSTRB
39
51
CMOS
O
Transmit strobe. TSTRB encodes transmit data.
XI_50
55
67
CMOS
I
External oscillator input. An external 49.152-MHz oscillator can drive the
TSB14C01A.
XI_100
52
64
CMOS
I
External oscillator input. An external 98.304-MHz oscillator can drive the
TSB14C01A.
NAME
DESCRIPTION
Table 1. External Priority Coding
EXTERNAL PRIORITY TERMINALS
ENA_PRI
EN_EXPRI
DESCRIPTION
EX_PRI0 – EX_PRI3
LLLL
LLLH
X
H
.
.
.
The priority for this node is determined by the values on EX_PRI0 – EX_PRI3.
The state of ENA_PRI can be either tied to VCC or GND.
HHHH
6
L
L
X
This sets a 7-bit bus request and is the cable environment format. Priority must be
set by executing a write request (see Table 10).
H
L
X
This sets an 11-bit bus request and is the backplane environment format. Priority
is dynamically set as part of the bus request (see Table 8)
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
absolute maximum ratings over operating free-air temperature range (unless otherwise noted)†
Supply voltage range, VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 0.5 V to 6.0 V
Input voltage range, VI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 0.5 V to VCC + 0.5 V
Output voltage range at any output, VO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 0.5 V to VCC + 0.5 V
Continuous total power dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . See Dissipation Rating Table
Operating free air temperature, TA: TSB14C01A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0°C to 70°C
TSB14C01AI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 40°C to 85°C
TSB14C01AM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 55°C to 125°C
Storage temperature range, Tstg . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 65°C to 150°C
Lead temperature 1,6 mm (1/16 inch) from case for 10 seconds . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 300°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.
DISSIPATION RATING TABLE
DERATING FACTOR‡
TA = 70°C
POWER RATING
ABOVE TA = 25°C
PACKAGE
TA ≤ 25°C
POWER RATING
HV
1689 mW
13.5 mW/°C
PM
1602 mW
12.8 mW/°C
TA = 85°C
POWER RATING
TA = 125°C
POWER RATING
1081 mW
879 mW
337 mW
1025 mW
833 mW
—
‡ This is the inverse of the traditional junction-to-ambient thermal resistance (RθJA) and uses a board-mounted RθJA of 78°C/W for the PM package
and 74°C/W for the HV package.
recommended operating conditions
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Supply voltage, VCC
High level input voltage,
High-level
voltage VIH
Low level input voltage,
voltage VIL
Low-level
Input voltage, VI
High level output current,
High-level
current IOH
Low level output current
Low-level
current, IOL
Virtual Junction Temperature, TJ §
Operating Free-Air Temperature, TA
CMOS inputs
MIN
NOM
MAX
UNIT
4.5
5
5.25
V
0.7 VCC
TTL input
2
CMOS inputs
0
TTL input
CMOS/TTL
V
VCC
0.2 VCC
V
0
0.8
V
0
VCC
12
V
CMOS Drivers
TTL Drivers
8
CMOS Drivers
24
TTL Drivers
8
TSB14C01A
115
TSB14C01AI
125
TSB14C01AM
150
TSB14C01A
0
70
TSB14C01AI
– 40
85
TSB14C01AM
– 55
125
V
mA
mA
°C
°C
§ Actual junction temperature is a function of ambient temperature, package selection, power dissipation, and air flow. Customer is responsible
for maintaining the junction temperature within the recommended operating conditions. Operating device at junction temperatures higher than
what is recommended will cause device to operate outside the characterization models established during device simulation and may affect the
reliability performance.
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
7
TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
electrical characteristics over recommended ranges of operating conditions (unless otherwise
noted)
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device
PARAMETER
VOH
VOL
TEST CONDITIONS
High-level output voltage
IOH = max,
IOL = min,
Low-level output voltage
Input current
IOZ
VCC = min
VCC = max
MIN
TYP
MAX
VCC– 0.8
V
VI = VCC or 0
VI = VCC or 0
Off-state output current
UNIT
0.5
V
±1
µA
± 10
µA
MAX
UNIT
thermal characteristics†
PARAMETER
RθJA
RθJC
TEST CONDITION
TSB14C01APM,
TSB14C01AIPM
Junction-to-free-air thermal resistance
Junction-to-case thermal resistance
MIN
TYP
78
°C/W
TSB14C01AMHV
74
°C/W
TSB14C01APM,
TSB14C01AIPM
16
°C/W
TSB14C01AMHV
3
°C/W
Board mounted,, No air flow
† Thermal characteristics vary depending on die, leadframe, pad size, and mold compound. These values represent typical die and pad sizes for
the respective package. The RθJA value decreases as the die pad size increases. Thermal values represent PWB bands with minimal amount
of metal.
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switching characteristics, VCC = 5 V, TA = 25°C (See Note 1)
PARAMETER
tsu
th
MEASURED
TEST CONDITION
MIN
D, CTL, LREQ low or high before SCLK high
50% to 50%
See Figure 1
7
D, CTL, LREQ low or high after SCLK high
50% to 50%
See Figure 1
1
td
Delay time, SCLK high to D, CTL high or low
50% to 50%
See Figure 2
NOTE 1: These parameters are ensured by design and are not production tested.
PARAMETER MEASUREMENT INFORMATION
SCLK
50%
tsu
th
D, CTL, LREQ
Figure 1. D, CTL, LREQ Input Setup and Hold Timing Waveforms
SCLK
50%
td
D, CTL
Figure 2. D, CTL Output Delay Relative to SCLK Timing Waveforms
8
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
TYP
MAX
UNIT
ns
ns
10
ns
TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
APPLICATION INFORMATION
internal register configuration
The accessible internal registers of this device are listed in Table 2. Bit field descriptions for the registers are
given in Table 3.
Table 2. Format for Registers
ADDRESS
0
1
2
3
4
5
6
7
0000
Physical
ID[0]
Physical
ID[1]
Physical
ID[2]
Physical
ID[3]
Physical
ID[4]
Physical
ID[5]
Reserved
Reserved
0001
INHB
IBR
Priority
level[0]
Priority
level[1]
RESERVED
0011
RESERVED
0100
Priority
level[2]
Priority
level[3]
RESERVED
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Table 3. Register Bit Field Key
FIELD
SIZE
(Bits)
TYPE
DESCRIPTION
Physical ID
6
Read/Write
Physical identification. Physical ID is the address of the local node and is set to zero on power up.
INHB
1
Read/Write
Inhibit Drivers. INHB is used to turn off the drivers to TDATA and TSTRB.
IBR
1
Read/Write
Initiate Bus Reset. IBR is turned on by the link and turned off by the phy when reset is complete.
Priority
4
Read/Write
Priority setting. The four bits contain the priority of the local node. A higher value in this field
indicates a higher priority.
transceiver selection
The system designer must select transceivers appropriate to the system requirements to be used with the
TSB14C01A and the link layer selected. The following lists requirements for the transceivers needed.
D
The transceivers used must be appropriate to the backplane technology used.
The various backplane technologies require different electrical characteristics in their backplanes. For
example BTL uses an operating voltage on the backplane of 2.1 V and a characteristic impedance of 33 Ω
while GTL uses an operating voltage of 1.2 V and a characteristic impedance of 50 Ω (see GTL/BTL a Low
Swing Solution for High-Speed Digital Logic, TI literature number SCEA003). When a backplane is
designed to use BTL technology, then it would be appropriate to also use that technology for the two lines
dedicated to the 1394 serial bus. The drivers selected also must be able to supply the current required for the
expected backplane loading. For example, BTL operates correctly for a FutureBus configuration backplane
at 50 Mbits/s or for a limited number of nodes in a custom configuration at 100 Mbits/s. See the GTL/BTL a
Low Swing Solution for High-Speed Digital Logic, TI literature number SCEA003, Understanding Advanced
Bus-Interface Products, TI literature number SCAA029, or the documentation for the transceiver being
considered.
D
The transceivers used must assert logic states on the backplane in an appropriate manner for the 1394
backplane arbitration.
Arbitration under 1394 backplane rules requires the drivers to assert the bus to indicate a logical 1 state, that
is a logic 1 being driven by the TSB14C01A. Conversely, the drivers should release the bus to indicate a
logic 0 state, a logic 0 being driven by the TSB14C01A. In other words, all drivers must operate in a wired-OR
mode during arbitration.
D
The transceivers used must be able to monitor the bus and drive the bus at the same time.
POST OFFICE BOX 655303
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TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
During arbitration, each node that is arbitrating for the bus drives its priority code then its node number out
onto the bus. During each bit period, each node reads back what has been placed on the bus. If it reads back
the same data it was sending, the arbitrating node stays in contention for winning the bus. If it reads
something different than what it was driving, the arbitrating node loses the bus and drops out of contention.
This is the reason for requiring wired-OR operation during arbitration. As long as each node is still sending
0s onto the bus during arbitration, all nodes are still contending to win the bus. The node with the highest
priority (or if all priorities were zero then the highest node number) is the first to drive a 1 onto the bus during
arbitration. The node that sends the first 1 (asserting the bus) and reads it back wins the bus. All other nodes
read back a 1, which does not match the 0 (releasing the bus) they are sending, and drop out of contention.
This arbitration process requires the transceiver selected to be able to read from the bus at the same time it
is driving the bus.
For example, if three nodes, each with priority 0 and a node identifiers of 8, 7, and 2, were to arbitrate for the
bus, the following would occur (see Figure 3):
Driven by Node #2
(TSB14C01A)
0
0
0
0
0
0
0
0
0
0
Driven by Node #7
(TSB14C01A)
0
0
0
0
0
0
0
0
0
0
Driven by Node #8
(TSB14C01A)
0
0
0
0
0
0
1
0
0
0
Bus Data Line
(voltage level on the bus)
Bus Read
NOTE A: This bus is reverse logic, a 1 being driven by the TSB14C01A is asserted by driving a 0 onto the bus by the transceiver.
Figure 3. Three Nodes Arbitrating for the Bus
Since the highest node number is 8 (1000b), node 8 outputs the first 1 (assert the bus) and wins the
arbitration. The other nodes drop out and do not try to drive their node number onto the bus.
D
The transceivers used must be appropriate for the transfer speed required.
The 1394 bus has two data lines that use data-strobe encoding on the bus. This requires that the
transceivers be able to operate at a maximum frequency of one half of the maximum data transfer rate.
When operating at 50 Mbits/s, the maximum frequency the drivers are required to operate at is 25 MHz.
When operating at 100 Mbits/s, the maximum frequency the drivers are required to operate at is 50 MHz.
10
POST OFFICE BOX 655303
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TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
PRINCIPLES OF OPERATION
The TSB14C01A (phy) is designed to operate with a link such as the Texas Instruments TSB12C01A. These
devices use an interface such as described in Annex J of the IEEE 1394-1995 standard. Details of how the
TSB12C01A device operates are given in the TSB12C01A data manual (literature number SLLS219). For
information on the operation of 1394, see the IEEE 1394-1995 standard. For more specific information on the
backplane phy, see the following sections of IEEE 1394-1995 standard: Chapter 5, Backplane physical layer
specification; Annex D, Backplane physical layer timing; Annex F, Backplane physical implementation example;
Annex G, Backplane isochronous resource manager selection. The following paragraphs describe the
operation of the phy-link interface.
The TSB14C01A supports 100 Mbit/s data transfers and has two bidirectional data lines (D0 and D1) crossing
the interface. In addition there are two bidirectional control lines (CTL0 and CTL1), the SCLK line from the phy
to the link, and the link request line (LREQ) from the link to the phy. The TSB14C01A phy has control of all the
bidirectional terminals. The link is allowed to drive these terminals only after it has been given permission by
the phy. The dedicated LREQ request terminal is used by the link for any activity that it can initiate.
There are four basic operations that can occur in the interface: request, status, transmit, and receive. All
operations but request are initiated by the phy. The link uses the request operation to read or write an internal
phy register or to ask the phy to initiate a transmit action. The phy initiates a receive action whenever a packet
is received from the serial bus.
When the phy has control of the bus, the CTL0 and CTL1 lines are encoded as shown in Table 4.
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Table 4. CTL0 and CTL1 Control Lines When the Phy Has Control
CTL0
CTL1
Name
Description of Activity
0
0
Idle
No activity is occurring (this is the default mode).
0
1
Status
Status information is being sent from the phy to the link.
1
0
Receive
An incoming packet is being sent from the phy to the link.
1
1
Transmit
The link has been given control of the bus to send an outgoing packet.
When the link has control of the bus (only with phy permission) the CTL0 and CTL1 lines are encoded as shown
in Table 5.
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Table 5. CTL0 and CTL1 Control Lines When the Link Has Control
CTL0
CTL1
Name
Description of Activity
0
0
Idle
The link releases the bus (the transmission has been completed).
0
1
Hold
The link is holding the bus while data is being prepared for transmission or sending another
packet without arbitrating.
1
0
Transmit
An outgoing packet is being sent from the link to the phy.
1
1
Reserved
None
When the link needs to request the bus or access a register that is located in the TSB14C01A phy, a serial stream
of information is sent across the LREQ line. The length of the stream varies depending on whether the transfer
is a bus request, a read command, or a write command (see Table 6). Regardless of the type of transfer, a start
bit of 1 is required at the beginning of the stream, and a stop bit of 0 is required at the end of the stream. Bit 0
is the MSB, and is transmitted first. The LREQ line is required to idle low (logic level 0).
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TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
PRINCIPLES OF OPERATION
Table 6. Request Bit Length
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Request Type
Number of
Bits
Bus request (cable)
7
Bus request (backplane)
11
Read register request
9
Write register request
17
For a bus request in the cable environment, the length of the LREQ data stream is 7 bits as shown in Table 7.
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Table 7. Bus Request For Cable Environment
Bit(s)
0
Name
Description
Start bit
Indicates the beginning of the transfer (always 1).
1-3
Request type
Indicates the type of bus request (see Table 11 for the encoding of this
field).
4-5
Request speed
Indicates the speed at which the phy sends the packet for this request. This
field has the same encoding as the speed code from the first symbol of the
receive packet. See Table 8 for the encoding of this field. This field can be
expanded to support data rates higher than 400 Mbit/s in the future.
Stop bit
Indicates the end of the transfer (always 0).
6
When LREQ transfer is a bus request in the backplane environment, it is 11 bits long and has the format shown
in Table 8.
Table 8. Bus Request For Backplane Environment
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Bit(s)
0
Name
Description
Start bit
Indicates the beginning of the transfer (always 1).
1-3
Request type
Indicates the type of bus request (see Table 11 for the encoding of this
field).
4-5
Request speed
Ignored (set to 00) for the backplane environment
6-9
Request priority
Indicates priority of urgent requests. It is only used with a FairReq request
type. All zeros indicates fair request.
All ones is reserved (this priority is implied by a PriReq).
Other values are used to indicate the priority of an urgent request.
10
Stop bit
Indicates the end of the transfer (always 0).
For a Read Register Request the length of the LREQ data stream is 9 bits as shown in Table 9 (also see Table 3
for the bit definitions).
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Table 9. Read Request Format
Bit(s)
0
12
Name
Description
Start bit
Indicates the beginning of the transfer (always 1).
1-3
Request type
Always a 100 indicating that this is a read register request.
4-7
Address
Is the address of the phy register to be read.
8
Stop bit
Indicates the end of the transfer (always 0).
POST OFFICE BOX 655303
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5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
PRINCIPLES OF OPERATION
For a Write Register Request the length of the LREQ data stream is 17 bits as shown in Table 10 (see Table 2
for the bit field format).
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Table 10. Write Request Format
Bit(s)
0
Name
Description
Start bit
Indicates the beginning of the transfer (always 1).
1-3
Request type
Always a 101 indicating that this is a write register request.
4-7
Address
The address of the phy register to be written to.
8-15
Data
The data that is to be written to the specified register address.
Stop bit
Indicates the end of the transfer (always 0).
16
The 3-bit request field is defined in Table 11.
Table 11. Request Field
LREQ1
LREQ2
LREQ3
0
0
0
0
0
1
0
1
0
0
1
1
Name
Description
ImmReq
Immediate request. When an idle is detected, the phy takes control of the bus
immediately (no arbitration)
IsoReq
Isochronous request. When an acknowledge gap is detected, the phy arbitrates for the
bus.
PriReq
Priority request. The phy arbitrates after a subaction gap and ignore fair protocol. PriReq
is used for cycle master request.
Fair/Urgent Req
Fair or urgent request. The phy arbitrates after a subaction gap using fair protocol.
Fair/Urgent Req is used for fair transfers with the request priority field differentiating fair
and urgent transfers for the backplane environment.
1
0
0
RdReg
Read register. Returns the specified register contents through a status transfer
1
0
1
WrReg
Write register. Writes to the specified register
1
1
1
1
0
1
Reserved
Reserved
LREQ Timing (each cell represents one clock sample time) is shown in Figure 4.
LReq0
LReq1
LReq2
LReq3
LReqn
Figure 4. LREQ Timing
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5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
PRINCIPLES OF OPERATION
bus request
For fair or priority access, the link requests control of the bus at least one clock after the phy-link interface
becomes idle. When the link senses that the CTL terminals are in a receive state (CTL 0 and CTL1 = 10), then
it knows that its request has been lost. This is true anytime during or after the link sends the bus request transfer.
Additionally, the phy ignores any fair or priority requests if it asserts the receive state while the link is requesting
the bus. The link then reissues the request one clock after the next interface idle.
The cycle master node uses a priority request (PriReq) to send the cycle start message. To request the bus to
send isochronous data, the link can issue the request at any time after receiving the cycle start. The phy clears
an isochronous request only when the bus has been won.
To send an acknowledge, the link must issue an ImmReq request during the reception of the packet addressed
to it. This is required because the delay from end-of-packet to acknowledge request adds directly to the
minimum delay every phy must wait after every packet to allow an acknowledge to occur. After the packet ends,
the phy immediately takes control of the bus and grants the bus to the link. If the header cyclic redundancy check
(CRC) of the packet turns out to be bad, the link releases the bus immediately. The link cannot use this grant
to send another type of packet. To ensure this, the link must wait 160 ns after the end of the received packet
to allow the phy to grant it the bus for the acknowledgement, then releases the bus and proceeds with another
request.
Although highly improbable, it is conceivable that two separate nodes can believe that an incoming packet is
intended for them. The nodes then issue an ImmReq request before checking the CRC of the packet. Since both
phys seize control of the bus at the same time, a temporary, localized collision of the bus occurs somewhere
between the competing nodes. This collision would be interpreted by the other nodes on the network as being
a ZZ line state, not a bus reset. As soon as the two nodes check the CRC, the mistaken node drops its request
and the false line state is removed. The only side effect would be the loss of the intended acknowledgment
packet (this is handled by the higher-layer protocol).
Once the link issues an immediate, isochronous, fair, or priority request for access to the bus, it cannot issue
another request until the phy indicates a lost (incoming packet) or won (transmit) signal. The phy ignores new
requests while a previous request is pending.
read/write requests
For write requests, the phy takes the value in the data field (see Table 2) of the transfer and loads it into the
addressed register as soon as the transfer is complete. For read requests (see Table 2), the phy returns the
contents of the addressed register at the next opportunity through a status transfer. The link is allowed to perform
a read or write operation at any time. When the status transfer is interrupted by an incoming packet, the phy
continues to attempt the transfer of the requested register until it is successful.
14
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SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
PRINCIPLES OF OPERATION
status
When the phy has status information to transfer to the link, it initiates a status transfer. The phy waits until the
interface is idle to perform the transfer. The phy initiates the transfer by asserting status (01) on the CTL
terminals, along with the first two bits of status information on D0 and D1. The phy maintains CTL == status for
the duration of the status transfer. The phy can temporarily halt a status transfer by asserting something other
than status on the CTL terminals. This is done in the event that a packet arrives before the status transfer
completes. There must be at least one idle cycle between consecutive status transfers.
The phy normally sends only the first 4 bits of status to the link. These bits are status flags that are needed by
link state machines. The phy sends an entire status packet to the link after a request transfer that contains a
read request.
The definition of the bits in the status transfer are shown in Table 12 (also see Table 2 and Table 9). The 16-bit
status stream is defined in Table 12.
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ÁÁÁÁ
ÁÁÁÁÁ
ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ
ÁÁÁÁ
ÁÁÁÁÁ
ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ
ÁÁÁÁ
ÁÁÁÁÁ
ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ
Table 12. Status Bit Description
Bit(s)
Name
Description
0
Arbitration
Reset gap
Indicates that the phy has detected that the bus has been idle for an
arbitration reset gap time (this time is defined in the 1394 standard). This bit
is used by the link in its busy/retry state machine.
1
Subaction gap
Indicates that the phy has detected that the bus has been idle for a subaction
gap time (this time is defined in the 1394 standard). This bit is used by the
link to detect the completion of an isochronous cycle.
2
Bus reset
Indicates that the phy has entered the bus reset state.
3
Reserved
Reserved
4-7
Address
Holds the address of the phy register whose contents are transferred to the
link.
8-15
Data
Indicates the data that is to be sent to the link.
Phy
CTL0, CTL1
00
00
01
01
01
00
00
Phy
D0, D1
00
00
S[0,1]
S[2,3]
S[14,15]
00
00
Figure 5. Status Transfer Timing
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PRINCIPLES OF OPERATION
transmit
When the link requests access to the serial bus through the LREQ terminal, the phy arbitrates for access to the
serial bus. When the phy wins the arbitration, it grants the bus to the link by asserting transmit on the CTL
terminals for one SCLK cycle, followed by idle for one cycle. After sampling the transmit state from the phy, the
link takes over control of the interface by asserting either hold or transmit on the CTL terminals. The link asserts
hold to keep ownership of the bus while preparing data. The phy asserts the data-on state on the serial bus
during this time. When it is ready to begin transmitting a packet, the link asserts transmit on the CTL terminals
along with the first bits of the packet. After sending the last bits of the packet, the link asserts either idle or hold
on the CTL terminals for one cycle, and then idle for one additional cycle, before asserting those terminals to
a high-impedance state.
The hold state here indicates to the phy that the link needs to send another packet without releasing the bus.
The phy responds to this hold state by waiting the required minimum time and then asserting transmit as before.
This function would be used after sending an acknowledgement if the link intends to send a unified response,
or to send consecutive isochronous packets during a single cycle. The only requirement when sending multiple
packets during a single bus ownership is that all packets must be transmitted at the same speed, since the speed
of the packet transmission is set before the first packet.
As noted above, when the link has finished sending the last packet for the current bus ownership, it releases
the bus by asserting idle on the CTL terminals for two SCLK cycles. The phy begins asserting idle on the CTL
terminals one clock after sampling the second idle from the link. Note that whenever the D and CTL lines change
ownership between the phy and the link, there is an extra clock period allowed so that both sides of the interface
can operate on registered versions of the interface signals, rather than having to respond to a CTL state on the
next cycle.
It is not required that the link enter the hold state before sending the first packet when implementation permits
the link to be ready to transmit as soon as bus ownership is granted. The timing for a single packet transmit
operation is shown in Figure 6. In the diagram, D0 – Dn are the data symbols of the packet; ZZ represents the
high-impedance state.
16
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transmit timing
Single Packet
Phy
CTL0, CTL1
00
11
00
ZZ
ZZ
ZZ
ZZ
ZZ
ZZ
ZZ
ZZ
00
Phy
D0, D1
00
00
00
ZZ
ZZ
ZZ
ZZ
ZZ
ZZ
ZZ
ZZ
00
Link
CTL0, CTL1
ZZ
ZZ
ZZ
01
01
10
10
10
10
00
00
ZZ
Link
D0, D1
ZZ
ZZ
ZZ
00
00
D0
D1
D2
Dn
00
00
ZZ
Phy
CTL0, CTL1
ZZ
ZZ
ZZ
ZZ
00
00
11
00
ZZ
ZZ
ZZ
ZZ
Phy
D0, D1
ZZ
ZZ
ZZ
ZZ
00
00
00
00
ZZ
ZZ
ZZ
ZZ
Link
CTL0, CTL1
10
10
01
00
ZZ
ZZ
ZZ
ZZ
01
01
10
10
00
00
ZZ
ZZ
ZZ
ZZ
00
00
D0
D1
Continued Packet
Link
Dn-1
Dn
D0, D1
NOTE A: ZZ = High Impedance State
D0 = > Dn = Packet data
Figure 6. Transmit Timing
receive
When data is received by the phy from the serial bus, it transfers the data to the link for further processing. The
phy asserts receive (see Table 4) on the CTL lines and asserts each D terminal high. The phy indicates the start
of the packet by placing the speed code on the data bus. The phy then proceeds with the transmittal of the packet
to the link on the D lines while still keeping the receive status on the CTL terminals. Once the packet has been
completely transferred, the phy asserts idle on the CTL terminals, which completes the receive operation (see
Figure 7).
NOTE
The speed code is a phy-link protocol and is not included in the CRC.
Phy
CTL0, CTL1
00
10
10
10
10
10
10
00
00
Phy
D0, D1
00
11
11
SPD
D0
D1
Dn
00
00
NOTE A: SPD = Speed Code (For the backplane, this speed is fixed at D0, D1 = 00).
D0 to Dn = Packet data
Figure 7. Receive Timing
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SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
PRINCIPLES OF OPERATION
backplane phy connection
Within the backplane environment the serial bus is implemented with a pair of signals (STRB and DATA). The
topology is a simple pair of bussed signals as shown in Figure 8.
Backplane Chassis
Module
Module
Module
Module
Node
Node
Node
Node
Node
Node
PHY
PHY
PHY
PHY
PHY
PHY
STRB
DATA
NOTE A: On a given bus, there can be as many as 63 nodes. There is no restriction on the distribution of nodes
throughout modules on the bus. When more than one node occupies a module, they must share the
same transceivers.
Figure 8. Backplane Topology
The backplane environment can be implemented with a number of different interface technologies. These
include, but are not limited to: TTL for industry-standard transistor-transistor logic, BTL for backplane
transceiver logic as defined by IEEE Std 1194.1, and ECL for emitter-coupled logic.
In addition to the requirements specified by the application environment, the physical media of the serial bus
should meet the requirements defined for media attachment, media signal interface, and media signal timing.
Timing requirements must be met over the ranges specified in the application environment. These include
temperature ranges, voltage ranges, and manufacturing tolerances.
18
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PRINCIPLES OF OPERATION
definition of logic states
Drivers assert the bus to indicate a 1 logic state, or release the bus to indicate a 0 logic state. To assert the bus,
a driver sinks current. To release the bus, drivers are asserted to a high-impedance state or turned off, allowing
the bus signal to be pulled to the termination voltage of the bus.
NOTE
This typically results in a logical inversion of signals on TTL and BTL buses. Signals on ECL buses
typically are not inverted.
All drivers operate in a wired-ORed or open-collector mode during arbitration. Drivers can operate in a totem
pole mode during data packet and acknowledge transfers. In this mode, a driver can drive the bus into its
released state in order to decrease the rise time of the bus signal (referred to as a rescinding release with TTL
technology).
bit rates
Data transmission and reception occurs at 49.152 Mbit/s or 98.304 Mbit/s (±100 ppm). Regardless of the
interface technology, arbitration occurs at an arbitration clock rate of 49.152 MHz.
backplane transmit data timing
Edge separation is the minimum required time between any two consecutive transitions of the backplane bus
signals, as they appear from the output of the transmitters, whether they be transitions on the same signal or
transitions on the two separate signals. A minimum edge separation is required to ensure proper operation of
the data strobe bit-level encoding mechanism. TDATA and TSTRB have the relationship shown in Figure 9 and
Table 13.
t1
t1
t1
t1
TDATA
t2
t2
t2
t2
TSTRB
Figure 9. Minimum Edge Separation
ÁÁÁÁÁÁÁÁÁÁÁ
ÁÁÁÁÁÁ
ÁÁÁÁÁÁÁ
ÁÁÁ
ÁÁÁÁÁÁÁÁÁ
ÁÁÁÁÁÁ
ÁÁÁÁÁÁÁ
ÁÁÁÁÁÁÁÁÁÁÁ
ÁÁÁ
ÁÁÁÁÁÁÁÁÁ
ÁÁÁÁÁÁ
ÁÁÁÁÁÁÁ
ÁÁÁ
ÁÁÁÁÁÁÁÁÁ
ÁÁÁÁÁÁ
ÁÁÁÁÁÁÁ
Table 13. TSB14C01A to Backplane Transceiver Timing
PARAMETER
98.304 MHz
49.152 MHz
t1
Bit cell period for data
9.44 ns minimum
19.44 ns minimum
t2
Transmit (Tx) edge separation
8.65 ns minimum
18.65 ns minimum
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PRINCIPLES OF OPERATION
backplane receive data timing
The receiver typically uses the transitions on the incoming bus signals RDATA and RSTRB to derive a clock
at the code bit frequency to extract the NRZ signal on RDATA. This clock can be derived by performing an
exclusive-OR (XOR) of RDATA and RSTRB.
The bus signals, as they appear from the backplane transceiver media and into the receivers, should be within
the constraints outlined by Figure 10.
t1
t1
t1
t1
RDATA
t3
t2
t3
t2
RSTRB
Figure 10. Backplane Receive Data Timing
ÁÁÁÁÁÁÁÁÁÁÁÁ
ÁÁÁÁÁÁÁ
ÁÁÁÁÁÁÁ
ÁÁÁÁ
ÁÁÁÁÁÁÁÁÁ
ÁÁÁÁÁÁÁ
ÁÁÁÁÁÁÁ
ÁÁÁÁÁÁÁÁÁÁÁÁ
ÁÁÁÁ
ÁÁÁÁÁÁÁÁÁ
ÁÁÁÁÁÁÁ
ÁÁÁÁÁÁÁ
ÁÁÁÁ
ÁÁÁÁÁÁÁÁÁ
ÁÁÁÁÁÁÁ
ÁÁÁÁÁÁÁ
ÁÁÁÁ
ÁÁÁÁÁÁÁÁÁ
ÁÁÁÁÁÁÁ
ÁÁÁÁÁÁÁ
Table 14. TSB14C01A to Backplane Transceiver Timing
PARAMETER
t1
t2†
Bit cell period
98.304 Mhz
10.1715 ns nominal
Receive (Rx) edge separation
49.152 MHz
20.34 ns nominal
3.4 ns minimum
3.4 ns minimum
16.3 ns maximum
36.6 ns maximum
t3
Receive (Rx) edge separation
† This parameter is based on a maximum total transmit skew of 2 ns and a maximum backplane skew
of 0.5 ns. This assumes total receive skew is less than receive edge separation (i.e., some skew
margin exists).
backplane timing definitions
D
D
D
D
D
D
20
Logic Skew — The skew between data and strobe within the physical layer itself due to internal skews
between data and strobe logic.
Spatial Skew — The skew between data and strobe due to differences in propagation delays along the
transmission line from arbiter to transceiver. This board delay is of concern when the physical layer and
transceivers are packaged separately.
Package Skew — The propagation delay difference through the transceiver between the data and strobe
channels.
Backplane Skew — The skew along the backplane itself due to impedance and/or mismatching of lengths
in the data and strobe lines.
Receive Setup/Hold — The setup and hold time needed to latch in the incoming data within the phy arbiter,
based off of the recovered clock from Data-Rx and Strobe-Rx.
Total Transmit Skew — The total skew between data and strobe in transmitting data from the phy out to the
bus. This is given by the following equation.
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Total Transmit Skew
D
Total Receive Skew — The total skew between data and strobe in receiving data from the bus into the phy.
This is given by the following equation.
Total Receive Skew
D
D
+ Receive Package Skew ) Spatial Skew ) Receive Setup ) Receive Hold
Skew Margin — The bit cell period minus all skews. This is given by the following equation.
Skew Margin
D
+ Transmit Package Skew ) Spatial Skew ) Logic Skew
+ Bit Cell Period * Total Transmit Skew * Backplane Skew * Total Receive Skew
Transmit Edge Separation — The minimum time required between any two consecutive transitions of the
bus signals to ensure proper operation of data-strobe bit level encoding. Transmit edge separation is
measured from the midpoint of the signal transition to the midpoint of the next signal transition out on the
bus. Minimum transmit edge separation is the minimum bit cell period less the maximum total transmit skew.
Receive Edge Separation — The minimum time required between any two consecutive transitions of the
bus signals to ensure proper operation of data-strobe bit level decoding. Receive edge separation is
measured from the midpoint of the signal transition to the midpoint of the next signal transition out on the
bus. This is the minimum bit cell period reduced by the amount of maximum total transmit skew and
maximum backplane skew.
gap timing
A gap is a period of time during which the bus is idle (Data_Rx and Strb_Rx are unasserted). There are three
types of gaps:
D
D
D
Acknowledge Gap — Appears between the end of a packet and an acknowledge, as well as between
isochronous transfers. A node should detect the occurrence of an acknowledge gap after the bus has been
in an unasserted state for 4 arbitration clock times (approximately 81.38 ns), but should not assert the bus
until a total of 8 arbitration clock times (approximately 182.76 ns) have occurred. This requirement ensures
that a node is given adequate time to detect the acknowledge gap before the bus is asserted by another
node upon detecting an acknowledge gap. This includes the minimum time required to detect a BUS_IDLE
(4 arbitration clock times), as well as the maximum delay between the arbitration state machines within any
two nodes on the bus (another 4 arbitration clock times).
Subaction Gap — Appears before asynchronous transfers within a fairness interval. A node should detect
the occurrence of a subaction gap after the bus has been in an unasserted state for at least 16 arbitration
clock times (approximately 325.52 ns), but should not assert the bus until a total of 20 arbitration clock times
(approximately 406.9 ns) have occurred. This requirement ensures that a node is given adequate time to
detect the subaction gap before the bus is asserted by another node (upon detecting a subaction gap). The
duration of the subaction gap ensures that another node asserting the bus after an acknowledge gap has
been detected by this time.
Arbitration Reset Gap — Appears before asynchronous transfers when the fairness interval starts. A node
should detect the occurrence of an arbitration reset gap after the bus has been in an unasserted state for
at least 28 arbitration clock times (approximately 569.66 ns), but should not assert the bus until a total of
32 arbitration clock times (approximately 651.04 ns) have occurred. This requirement ensures that a node
is given adequate time to detect the arbitration reset gap before the bus is asserted by another node (upon
detecting an arbitration reset gap). The duration of the arbitration reset gap ensures that another node
asserting the bus after a subaction gap or an acknowledge gap has been detected by this time.
If a node is waiting for the occurrence of a particular gap, and the bus has become idle for the specified time
(e.g., 32 arbitration clock times for an arbitration reset gap), the node detects the gap and asserts the bus within
the time constraints described under the bus synchronization and propagation delay section of this document.
These constraints ensure that an asserted signal propagates through the node decision/transceiver circuitry
and onto the bus soon enough to allow arbitration to occur properly.
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PRINCIPLES OF OPERATION
arbitration sequence
The arbitration sequence is the process that the TSB14C01A uses to arbitrate the bus between competing
modules.
arbitration number
The arbitration sequence uses a unique arbitration number for each module. This 6-bit number is the same as
the node physical_ID. When less than 6 bits are provided for the arbitration number, they occupy the MSBs of
the arbitration number. The remaining bits are zero-filled. The MSBs are transmitted first.
NOTE
If the serial bus is contained within a host backplane, it is expected that the arbitration number (i.e.,
physical_ID) is set by the host backplane at power up (e.g., with a built-in slot identifier or
configuration mechanism).
It is recommended that this number be software programmable to facilitate testing and to allow for consistent
system operation and repeatability.
priority
Within the arbitration sequence, the arbitration number is preceded by four bits that define a priority level. The
method by which priority is assigned is to be determined by the system integrator with two exceptions. The
lowest priority (all zeros) is reserved for fair arbitration and the highest priority (all ones) is reserved for cycle
start requests. This allows 14 priority levels to be used for the urgent arbitration process.
The use of an urgent priority class allows nodes to be granted a larger portion of the bandwidth on the bus. High
priority nodes are granted the bus before lower priority nodes during urgent allocation of the bus, allowing such
nodes to be granted more bandwidth.
In order to ensure forward progress, the lowest priority level is reserved for fair arbitration. This allows all nodes
arbitrating with this priority level to be allowed one fair access to the bus for each fairness interval. For fair
arbitration, the value of the arbitration number has a minimal impact on the allocation of the bus. Although nodes
with higher arbitration numbers are granted the bus sooner, there is only a small decrease in latency.
The 4-bit priority field is not used in isochronous arbitration. When arbitrating for an isochronous transfer, the
priority field is zero-filled.
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PRINCIPLES OF OPERATION
format of arbitration sequence
The following format for the arbitration sequence should be used:
PRIORITY
ARBITRATION NUMBER
4 bits
6 bits
arbitration sequence
D
D
D
D
Each module on the backplane has a unique 6-bit arbitration number that is equal to the node’s physical_ID.
The arbitration number is preceded by four bits of priority. The MSB of the priority field is transmitted first.
The LSB of the priority field is followed by the MSB of the arbitration number.
Dynamic assignment of priority is accommodated.
The lowest priority level (all zeroes) is reserved for fair arbitration, and the highest priority level (all ones)
is reserved for the identification of the cycle start packet.
arbitration
Unless a node is using immediate arbitration to access the bus (in which case there is no contention for the bus),
it is possible that more than one node can attempt to access the bus at a given time. Consequently, it is
necessary for a node to arbitrate for the bus in order to gain access to the bus.
NOTE
A node uses immediate arbitration to send an acknowledge. Since there is no contention for the
bus in this case, arbitration is not necessary. A node that is transmitting an acknowledge does not
arbitrate for the bus, but merely waits for an acknowledge gap to be detected before it begins
transmission. If a node is attempting to gain access to the bus without using immediate access, it
must first arbitrate for the bus.
Arbitration occurs in response to a phy arbitration request from the link. Nodes begin arbitrating once the bus
has become idle for a predetermined amount of time (the appropriate gap indication occurs). Once this happens,
nodes begin a bit-by-bit transmission of their arbitration sequence.
A node can obtain access to the bus in a limited number of ways. Since some arbitration classes allow nodes
to begin arbitration before others, nodes arbitrating with certain arbitration classes can detect that the bus is
busy before they can begin to arbitrate. In this way, certain arbitration classes can be bypassed. For example,
fair and urgent nodes do not get a chance to arbitrate when another node is sending an acknowledge or when
it is arbitrating for an isochronous transfer.
The backplane environment supports the fair, urgent, cycle_master, isochronous, and immediate arbitration
classes.
fairness intervals
The fairness protocol is based on the concept of a fairness interval. A fairness interval consists of one or more
periods of bus activity separated by short idle periods called subaction gaps and is followed by a longer idle
period known as an arbitration reset gap. At the end of each gap, bus arbitration is used to determine the next
bus owner. This concept is shown in Figure 11.
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PRINCIPLES OF OPERATION
fairness intervals (continued)
Fairness
Interval (N +1)
Fairness Interval (N)
data
arb
arb
arb
data
ack
data
Owner M
ack
arb
Owner B
ack
Owner A
ack
ack
Fairness
Interval (N –1)
arb
Subaction
Arbitration
Reset Gap
Subaction Gaps
Arbitration
Reset Gap
Figure 11. Fairness Interval
The implementation of the fair arbitration protocol is defined in terms of these fairness intervals as discussed
in the following paragraphs.
fair arbitration
When using this arbitration class, an active node can send an asynchronous packet only once each fairness
interval. Once a subaction gap is detected, a node can begin arbitration when its arbitration_enable signal is
set. The arbitration_enable signal is set at the beginning of the fairness interval and is cleared when the node
successfully accesses the bus through fair arbitration. This disables further fair arbitration attempts by that node
for the remainder of the fairness interval. In the absence of urgent nodes, a fairness interval ends once all of
the nodes attempting fair arbitration have successfully accessed the bus. At this time, all of the fair nodes have
their arbitration_enable signals reset and cannot arbitrate for the bus. The bus remains idle until an arbitration
reset gap occurs. Once this happens, the next fairness interval begins. All of the nodes set their
arbitration_enable signal and can begin to arbitrate for the bus. This process is illustrated in Figure 12.
Fairness
Interval (N –1)
Fairness
Interval (N +1)
Fairness Interval (N)
arb
node A
arb
node B
arb
node C
arb
Node A
Arbitration
Enable
Node B
Node C
Arbitration
Reset Gap
Arbitration
Reset Gap
Set at Arbitration Reset Gap
Cleared When Node Wins Arbitration
NOTE A: The arbitration number of A > B > C.
Figure 12. Fair Arbitration Timing
Note that a node sending a concatenated subaction does not reset its arb_enable bit.
24
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PRINCIPLES OF OPERATION
urgent arbitration
The backplane environment enhances the fair priority algorithm by splitting access opportunities among nodes
based on two priority classes: fair and urgent. Nodes using an urgent priority can use up to three-fourths of the
access opportunities, with the remaining ones equally shared among nodes using the fair priority. All nodes are
required to implement the fair priority class, while the urgent priority class is optional. Packets are labeled as
urgent when that priority class was used.
The fair/urgent allocation uses the same fairness interval described in fair arbitration but accompanies the
arbitration_enable flag with an urgent_count. The fair/urgent method works as follows:
D
D
D
D
D
When the bus is idle for longer than an arbitration reset gap, a fairness interval begins and all nodes set
their arbitration_enable flags, while nodes implementing urgent priority set their urgent_count to three.
A node that is waiting to send a packet using the fair priority class should begin arbitrating after detecting
a subaction gap as long as its arbitration_enable flag is set. When its arbitration_enable flag is cleared, it
waits for an arbitration reset gap before it begins arbitrating. When such a node wins an arbitration contest,
it sends a packet without the urgent label and its arbitration_enable flag is cleared.
A node that is waiting to send a packet with urgent priority begins arbitrating after detecting a subaction gap
if its urgent_count is nonzero. When its urgent_count is zero, it waits for an arbitration reset gap before it
begins arbitrating. Whenever such a node wins an arbitration contest, it sends a packet with the urgent label.
A node implementing urgent priority sets its urgent_count to three whenever an unlabeled (i.e., fair) packet
is transmitted or received. This includes received packets that are addressed to other nodes.
A node decrements its urgent_count whenever a packet with the urgent label is transmitted or received. This
includes received packets that are addressed to other nodes. This ensures that there is at most three urgent
packets for every fair packet. This does not ensure that every node using urgent priority obtains the bus
three times for each fairness interval. The node arbitrating with the highest priority always obtains the bus
before other nodes arbitrating with an urgent, but lower, priority.
In the presence of urgent nodes, a fairness interval ends after the final fair node and up to three remaining urgent
nodes have successfully accessed the bus. Since all fair nodes now have their arbitration_enable signals reset
and all urgent nodes have their urgent_count decremented to zero, none of the nodes can access the bus. The
bus remains idle until an arbitration reset gap has occurred, re-enabling arbitration on all nodes and starting the
next fairness interval. This process is illustrated in Figure 13, which illustrates a situation where there are three
nodes arbitrating for the bus with physical_IDs such that A has the highest priority, B is in the middle priority,
and C has the lowest priority, with nodes A and C using fair priority and B using urgent:
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SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
PRINCIPLES OF OPERATION
urgent arbitration (continued)
A Node Using The Urgent
Protocol Has a Higher Priority
Than Any Fair Node
Fairness Interval (N)
Fairness
Interval (N –1)
Urgent
Packet
Urgent
Packet
Urgent
Packet
Fair
Packet
Urgent
Packet
Urgent
Packet
arb Node B
arb Node B
arb Node B
arb Node A
arb Node B
arb Node B
Node A
Arbitration_Enable
Urgent_Count Incremented By
Urgent_Count Set
3 After A Fair Node (A) Wins
To 3 At Arbitration Arbitration and Sends A Packet
Reset Gap
Node B
Urgent_Count
3
2
Arbitration_Enable Set At
Arbitration Reset Gap
1
3
1
2
Node C
Arbitration_Enable
Urgent_Count Decremented
When Urgent Node Sends A Packet
Arbitration
Reset Gap
Arbitration_Enable Set
at Arbitration Reset Gap
Fairness
Interval (N +1)
Fairness Interval (N)
Urgent
Packet
arb
Node B
Fair
Packet
Urgent
Packet
Urgent
Packet
Urgent
Packet
arb Node C
arb Node B
arb Node B
arb Node B
Node A
Urgent_Count Incremented By 3
After A Fair Node (C) Wins Arbitration
and Sends A Packet
Arbitration_Enable Set At
Arbitration Reset Gap
Node B
3
2
1
3
Node C
Arbitration
Reset Gap
Figure 13. Urgent Arbitration
26
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
PRINCIPLES OF OPERATION
urgent arbitration (continued)
In the backplane environment, the natural priority is the concatenation of the 4-bit urgent priority level with the
physical_ID. These results are listed in the following list.
D
D
D
A node using the urgent priority always wins an arbitration contest over all nodes using the fair priority.
The node using the highest priority level wins the arbitration contest.
When more than one node uses the highest priority level, then the one with the highest physical_ID wins.
arbitration by the cycle_master
This arbitration class is used by the cycle_master when it needs to arbitrate for the transmission of a cycle_start
packet. It is similar to the urgent arbitration class, except that the priority field is defined to be all ones. Arbitration
begins once a subaction gap is detected, regardless of the state of the arbitration_enable signal or the
urgent_count.
isochronous arbitration
This arbitration class is used by nodes arbitrating to send isochronous packets. Arbitration begins once an
acknowledge gap is detected, regardless of the state of the arbitration_enable signal or the urgent_count.
Because an acknowledge gap is shorter than an arbitration reset gap and a subaction gap, nodes arbitrating
with this class win the bus before nodes waiting to send fair, urgent, or cycle_master packets. The priority field
is not used in this arbitration class.
immediate arbitration
This arbitration class is used by nodes sending an acknowledge to a received packet. Transmission of the
acknowledge (beginning with a DATA_PREFIX) occurs as soon as an acknowledge gap is detected. This
arbitration class is referred to as immediate because an arbitration sequence is not transmitted to obtain access
to the bus (i.e., the node does not actually arbitrate for the bus).
backplane phy reset
Upon a power_reset event (i.e., power up), registers and control and status registers (CSRs) associated with
the operation of the phy are initialized to their default values. State machines associated with phy operations
are initialized. The BUS_RESET signal is not transmitted on the bus by the phy.
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27
TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
PRINCIPLES OF OPERATION
bus reset
Once a phy control request of bus reset is communicated from the node controller to the phy, the registers and
CSRs associated with the operation of that phy are initialized to their default values. State machines associated
with phy operations can be initialized. The phy communicates a BUS_RESET onto the bus. After the
BUS_RESET event is detected by the node transmitting it (i.e., approximately 320 arbitration clock times after
the signal is initiated), the phy initializes itself.
NOTE
Since a phy transmitting a BUS_RESET must also react accordingly once the BUS_RESET event
is detected, its state machines do have the opportunity to advance beyond those of other nodes.
This ensures that all nodes are in somewhat similar states after such a bus reset event. Obviously,
the logic (e.g., counters) used within the phy to generate the BUS_RESET signal must not be reset
once that phy simultaneously detects its own BUS_RESET.
Once a phy detects that a BUS_RESET event has occurred on the bus, it initializes itself. The node controller
initiates a bus reset by writing to the phy control register with the IBR bit set to 1. The phy hardware resets the
IBR bit to zero on detection of its own bus reset.
live insertion
It is up to the user to design their node or module to safely receive power from the particular backplane they
are using during a live insertion or tap-in. But in principal, live insertion is supported and does not cause a
bus-reset event to occur. Please see the TI application note, Live Insertion, TI literature number SDYA012.
28
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
MECHANICAL INFORMATION
HV (S-GQFP-F68)
CERAMIC QUAD FLATPACK
1.500 (38,10)
SQ
1.300 (33,02)
60
44
43
61
0.025 (0,635)
1
0.013 (0,330)
0.008 (0,203)
27
9
10
26
0.400 (10,16) TYP
0.500 (12,70)
SQ
0.485 (12,32)
0.007 (0,178)
0.154 (3,912)
0.005 (0,127)
0.134 (3,404)
4040072 / C 04/96
NOTES: A. All linear dimensions are in inches (millimeters).
B. This drawing is subject to change without notice.
C. This package can be hermetically sealed with a ceramic lid using glass frit.
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• DALLAS, TEXAS 75265
29
TSB14C01A, TSB14C01AI, TSB14C01AM
5-V IEEE 1394-1995 BACKPLANE TRANSCEIVER/ARBITER
SGLS107A – FEBRUARY 1999 – REVISED NOVEMBER 1999
MECHANICAL INFORMATION
PM (S-PQFP-G64)
PLASTIC QUAD FLATPACK
0,27
0,17
0,50
0,08 M
33
48
49
32
64
17
0,13 NOM
1
16
7,50 TYP
10,20
SQ
9,80
12,20
SQ
11,80
Gage Plane
0,25
0,05 MIN
0°– 7°
0,75
0,45
1,45
1,35
Seating Plane
0,08
1,60 MAX
4040152 / C 11/96
NOTES: A.
B.
C.
D.
30
All linear dimensions are in millimeters.
This drawing is subject to change without notice.
Falls within JEDEC MS-026
May also be thermally enhanced plastic with leads connected to the die pads.
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