SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
D High-Performance Floating-Point Digital
D
Signal Processor (DSP):
- SM/SMJ320VC33-150
- 13-ns Instruction Cycle Time
- 150 Million Floating-Point Operations
Per Second (MFLOPS)
- 75 Million Instructions Per Second
(MIPS)
34K × 32-Bit (1.1-Mbit) On-Chip Words of
Dual-Access Static Random-Access
Memory (SRAM) Configured in 2 × 16K plus
2 × 1K Blocks to improve Internal
Performance
D x5 Phase-Locked Loop (PLL) Clock
D
D
D
D
D
D
D
D
D
Generator
Very Low Power: < 200 mW @ 150 MFLOPS
32-Bit High-Performance CPU
16-/32-Bit Integer and 32-/40-Bit
Floating-Point Operations
Four Internally Decoded Page Strobes to
Simplify Interface to I/O and Memory
Devices
Boot-Program Loader
EDGEMODE Selectable External Interrupts
32-Bit Instruction Word, 24-Bit Addresses
Eight Extended-Precision Registers
Fabricated Using the 0.18-µm (leff-Effective
Gate Length) TImeline Technology by
Texas Instruments (TI)
D On-Chip Memory-Mapped Peripherals:
D
D
- One Serial Port
- Two 32-Bit Timers
- Direct Memory Access (DMA)
Coprocessor for Concurrent I/O and CPU
Operation
164-Pin Low-Profile Quad Flatpack (HFG
Suffix)
144-Pin Non-hermetic Ceramic Ball Grid
Array (CBGA) (GNM Suffix)
D Two Address Generators With Eight
D
D
D
D
D
D
D
D
D
Auxiliary Registers and Two Auxiliary
Register Arithmetic Units (ARAUs)
Two Low-Power Modes
Two- and Three-Operand Instructions
Parallel Arithmetic/Logic Unit (ALU) and
Multiplier Execution in a Single Cycle
Block-Repeat Capability
Zero-Overhead Loops With Single-Cycle
Branches
Conditional Calls and Returns
Interlocked Instructions for
Multiprocessing Support
Bus-Control Registers Configure
Strobe-Control Wait-State Generation
1.8-V (Core) and 3.3-V (I/O) Supply Voltages
description
The SM/SMJ320VC33 DSP is a 32-bit, floating-point processor manufactured in 0.18-µm four-level-metal
CMOS (TImeline) technology. The SM/SMJ320VC33 is part of the SM320C3x generation of DSPs from Texas
Instruments.
The SM320C3x internal busing and special digital-signal-processing instruction set have the speed and
flexibility to execute up to 150 million floating-point operations per second (MFLOPS). The SM/SMJ320VC33
optimizes speed by implementing functions in hardware that other processors implement through software or
microcode. This hardware-intensive approach provides performance previously unavailable on a single chip.
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.
TImeline and SM320C3x are trademarks of Texas Instruments.
Copyright 2002, Texas Instruments Incorporated
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of Texas Instruments
standard warranty. Production processing does not necessarily include
testing of all parameters.
POST OFFICE BOX 1443
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.
• HOUSTON, TEXAS 77251-1443
1
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
description (continued)
The SM/SMJ320VC33 can perform parallel multiply and ALU operations on integer or floating-point data in a
single cycle. Each processor also possesses a general-purpose register file, a program cache, dedicated
ARAUs, internal dual-access memories, one DMA channel supporting concurrent I/O, and a short
machine-cycle time. High performance and ease of use are the results of these features.
General-purpose applications are greatly enhanced by the large address space, multiprocessor interface,
internally and externally generated wait states, one external interface port, two timers, one serial port, and
multiple-interrupt structure. The SM320C3x supports a wide variety of system applications from host processor
to dedicated coprocessor. High-level-language support is easily implemented through a register-based
architecture, large address space, powerful addressing modes, flexible instruction set, and well-supported
floating-point arithmetic.
JTAG scan-based emulation logic
The 320VC33 contains a JTAG port for CPU emulation within a chain of any number of other JTAG devices.
The JTAG port on this device does not include a pin-by-pin boundary scan for point-to-point board level test.
The Boundary Scan tap input and output is internally connected with a single dummy register allowing loop back
tests to be performed through that JTAG domain.
The JTAG emulation port of this device also includes two additional pins, EMU0 and EMU1, for global control
of multiple processors conforming to the TI emulation standard. These pins are open collector-type outputs
which are wire ORed and tied high with a pullup. Non-TI emulation devices should not be connected to these
pins.
The VC33 instruction register is 8 bits long. Table 1 shows the instructions code. The uses of SAMPLE and
HIGHZ opcodes, though defined, have no meaning for the SM/SMJ320VC33, which has no boundary scan. For
example, HIGHZ will affect only the dummy cell (no meaning) and will not put the device pins in a
high-impedance state.
Table 1. Boundary-Scan Instruction Code
INSTRUCTION NAME
†
2
INSTRUCTION CODE
EXTEST
00000000
BYPASS
11111111
SAMPLE
00000010
Boundry is only one dummy cell
HIGHZ
00000110
Boundry is only one dummy cell
PRIVATE1†
00000011
PRIVATE2†
00100000
PRIVATE3†
00100001
PRIVATE4†
00100010
PRIVATE5†
00100011
PRIVATE6†
00100100
PRIVATE7†
00100101
PRIVATE8†
00100110
PRIVATE9†
00100111
PRIVATE10†
00101000
PRIVATE11†
00101001
Use of Private opcodes could cause the device to operate in an unexpected manner.
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251-1443
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
pinout
164
163
162
161
160
159
158
157
156
155
154
153
152
151
150
149
148
147
146
145
144
143
142
141
140
139
138
137
136
135
134
133
132
131
130
129
128
127
126
125
124
NC
NC
NC
A21
DV DD
A22
A23
V SS
RSV0
RSV1
CVDD
CLKMD0
CLKMD1
PLLV SS
XIN
XOUT
PLLV DD
EXTCLK
DV DD
SHZ
RESET
V SS
MCBL/MP
EDGEMODE
CV DD
INT0
INT1
INT2
INT3
V SS
XF0
XF1
DVDD
TCLK0
TCLK1
VSS
DX
FSX
CLKX0
NC
NC
HFG PACKAGE†‡
(TOP VIEW)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
123
122
121
120
119
118
117
116
115
114
113
112
111
110
109
108
107
106
105
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
NC
NC
NC
DVDD
CLKR
FSR0
VSS
DR0
TRST
TMS
CVDD
TDI
TDO
TCK
VSS
EMU0
EMU1
DVDD
D0
D1
D2
D3
VSS
D4
D5
DVDD
D6
D7
CVDD
D8
D9
VSS
D10
D11
DVDD
D12
D13
D14
D15
NC
NC
H1
H3
VSS
STRB
R/W
DV DD
IACK
RDY
CVDD
HOLD
HOLDA
VSS
D31
D30
D29
DVDD
D28
D27
VSS
D26
D25
D24
DV DD
D23
D22
VSS
D21
D20
CVDD
D19
D18
DV DD
D17
D16
VSS
NC
NC
DV DD
NC
NC
NC
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
NC
NC
NC
A20
VSS
A19
A18
A17
DVDD
A16
A15
VSS
A14
A13
CVDD
A12
A11
DVDD
A10
A9
VSS
A8
A7
A6
A5
DVDD
A4
VSS
A3
A2
CVDD
A1
A0
DVDD
PAGE3
PAGE2
VSS
PAGE1
PAGE0
NC
NC
NC - No internal connection
†
DVDD is the power supply for the I/O pins while CVDD is the power supply for the core CPU. VSS is the ground for both the I/O
pins and the core CPU.
‡ PLLV
DD and PLLVSS are isolated PLL supply pins that should be externally connected to CVDD and VSS, respectively.
The SM/SMJ320VC33 device is packaged in 164-pin low-profile quad flatpacks (HFG Suffix) and in 144-ball
fine pitch ball grid arrays (GNL and GNM Suffix).
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251-1443
3
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
GNM Terminal Assignments† (Sorted by Signal Name)
SIGNAL
NAME
PIN
NUMBER
SIGNAL
NAME
PIN
NUMBER
SIGNAL
NAME
PIN
NUMBER
SIGNAL
NAME
PIN
NUMBER
A0
J2
D0
G12
M1
R/W
L4
A1
K2
D1
G10
N1
RDY
M5
A2
K1
D2
F13
N4
RESET
B7
A3
J4
D3
G11
N7
RSV0
B4
A4
H4
D4
H10
M8
RSV1
D5
A5
H3
D5
H13
A6
H1
D6
H12
A7
G4
D7
J10
A8
G1
D8
A9
G2
D9
A10
F3
D10
N12
SHZ
D7
L13
STRB
M4
H11
TCK
F10
J11
F11
TCLK0
C10
J12
B12
TCLK1
A11
K13
A10
TDI
E11
DVDD
A11
F4
D11
K12
A6
TDO
D13
A12
F2
D12
K10
A1
TMS
E10
A13
E1
D13
M13
DX0
A12
TRST
C13
A14
E2
D14
L11
EDGEMODE
A7
B1
A15
E4
D15
L12
EMU0
F12
D1
A16
C1
D16
M12
EMU1
E12
G3
A17
C2
D17
L10
EXTCLK
C6
J1
A18
D3
D18
K9
FSR0
C12
L2
A19
C3
D19
N11
FSX
D10
M3
A20
B2
D20
M11
H1
L3
M6
A21
D4
D21
M10
H3
N2
L7
A22
A2
D22
K8
HOLD
N5
A23
B3
D23
N9
HOLDA
K5
CLKMD0
C5
D24
M9
IACK
K4
K11
CLKMD1
B5
D25
L8
INT0
C8
G13
CLKR0
B13
D26
N8
INT1
B9
E13
CLKX0
B11
D27
M7
INT2
D8
A13
E3
D28
K7
INT3
A9
C11
J3
D29
L6
MCBL/MP
B8
C9
L5
D30
N6
PAGE0
M2
C7
L9
D31
K6
PAGE1
N3
J13
DR0
D11
PAGE2
L1
XF0
B10
D2
PAGE3
K3
XF1
D9
F1
PLLVDD‡
A5
XIN
B6
H2
PLLVSS‡
A4
XOUT
D6
CVDD
D12
A8
A3
DVDD
†
N10
VSS
N13
C4
DVDD is the power supply for the I/O pins while CVDD is the power supply for the core CPU. VSS is the ground for both the I/O pins and the core
CPU.
‡ PLLV
DD and PLLVSS are isolated PLL supply pins that should be externally connected to CVDD and VSS, respectively.
4
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251-1443
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
GNM Terminal Assignments† (Sorted by Pin Number)
PIN
NUMBER
SIGNAL
NAME
A1
DVDD
A2
A22
A3
CVDD
A4
PLLVSS
A5
PIN
NUMBER
SIGNAL
NAME
PIN
NUMBER
SIGNAL
NAME
PIN
NUMBER
SIGNAL
NAME
C11
VSS
G10
D1
L4
R/W
C12
FSR0
G11
D3
L5
CVDD
C13
TRST
G12
D0
L6
D29
D1
VSS
G13
VSS
L7
VSS
PLLVDD
D2
DVDD
H1
A6
L8
D25
A6
DVDD
D3
A18
H2
DVDD
L9
CVDD
A7
EDGEMODE
D4
A21
H3
A5
L10
D17
A8
CVDD
D5
RSV1
H4
A4
L11
D14
A9
INT3
D6
XOUT
H10
D4
L12
D15
A10
DVDD
D7
SHZ
H11
DVDD
L13
DVDD
A11
TCLK1
D8
INT2
H12
D6
M1
DVDD
A12
DX
D9
XF1
H13
D5
M2
PAGE0
A13
VSS
D10
FSX
J1
VSS
M3
VSS
B1
VSS
D11
DR0
J2
A0
M4
STRB
B2
A20
D12
CVDD
J3
CVDD
M5
RDY
B3
A23
D13
TDO
J4
A3
M6
VSS
B4
RSV0
E1
A13
J10
D7
M7
D27
B5
CLKMD1
E2
A14
J11
D8
M8
DVDD
B6
XIN
E3
CVDD
J12
D9
M9
D24
B7
RESET
E4
A15
J13
CVDD
M10
D21
B8
MCBL/MP
E10
TMS
K1
A2
M11
D20
B9
INT1
E11
TDI
K2
A1
M12
D16
B10
XF0
E12
EMU1
K3
PAGE3
M13
D13
B11
CLKX0
E13
VSS
K4
IACK
N1
DVDD
B12
DVDD
F1
DVDD
K5
HOLDA
N2
H3
B13
CLKR
F2
A12
K6
D31
N3
PAGE1
C1
A16
F3
A10
K7
D28
N4
DVDD
C2
A17
F4
A11
K8
D22
N5
HOLD
C3
A19
F10
TCK
K9
D18
N6
D30
C4
VSS
F11
DVDD
K10
D12
N7
DVDD
C5
CLKMD0
F12
EMU0
K11
VSS
N8
D26
C6
EXTCLK
F13
D2
K12
D11
N9
D23
C7
VSS
G1
A8
K13
D10
N10
VSS
C8
INT0
G2
A9
L1
PAGE2
N11
D19
C9
VSS
G3
VSS
L2
VSS
N12
DVDD
C10
TCLK0
G4
A7
L3
H1
N13
VSS
†
DVDD is the power supply for the I/O pins while CVDD is the power supply for the core CPU. VSS is the ground for both the I/O pins and the core
CPU.
‡ PLLV
DD and PLLVSS are isolated PLL supply pins that should be externally connected to CVDD and VSS, respectively.
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251-1443
5
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
Terminal Functions
TERMINAL
NAME
QTY
TYPE†
DESCRIPTION
CONDITIONS
WHEN
SIGNAL IS Z TYPE‡
PRIMARY-BUS INTERFACE
32-bit data port
S
Data port bus keepers. (See Figure 9)
S
D31 D0
D31-
32
I/O/Z
A23- A0
24
O/Z
24-bit address port
H
R
S
H
R
S
H
R
R/W
1
O/Z
Read/write. R/W is high when a read is performed and low when a write is performed
over the parallel interface.
STRB
1
O/Z
Strobe. For all external-accesses
S
H
PAGE0 PAGE3
1
O/Z
Page strobes. Four decoded page strobes for external access
S
H
RDY
1
I
Ready. RDY indicates that the external device is prepared for a transaction
completion.
I
Hold. When HOLD is a logic low, any ongoing transaction is completed. A23- A0,
D31-D0, STRB, and R/W are placed in the high-impedance state and all
transactions over the primary-bus interface are held until HOLD becomes a logic high
or until the NOHOLD bit of the primary-bus-control register is set.
O/Z
Hold acknowledge. HOLDA is generated in response to a logic-low on HOLD.
HOLDA indicates that A23-A0, D31-D0, STRB, and R/W are in the high-impedance
state and that all transactions over the bus are held. HOLDA is high in response to
a logic-high of HOLD or the NOHOLD bit of the primary-bus-control register is set.
HOLD
HOLDA
1
1
R
S
CONTROL SIGNALS
RESET
1
I
Reset. When RESET is a logic low, the device is in the reset condition. When RESET
becomes a logic high, execution begins from the location specified by the reset vector.
EDGEMODE
1
I
Edge mode. Enables interrupt edge mode detection.
INT3- INT0
4
I
External interrupts
IACK
1
O/Z
MCBL/MP
1
I
Microcomputer Bootloader/microprocessor mode-select
Internal acknowledge. IACK is generated by the IACK instruction. IACK can be used
to indicate when a section of code is being executed.
SHZ
1
I
Shutdown high impedance. When active, SHZ places all pins in the high-impedance
state. SHZ can be used for board-level testing or to ensure that no dual-drive
conditions occur. CAUTION: A low on SHZ corrupts the device memory and register
contents. Reset the device with SHZ high to restore it to a known operating condition.
XF1, XF0
2
I/O/Z
External flags. XF1 and XF0 are used as general-purpose I/Os or to support
interlocked processor instruction.
CLKR0
1
I/O/Z
CLKX0
1
DR0
DX0
S
S
R
Serial port 0 receive clock. CLKR0 is the serial shift clock for the serial port 0 receiver.
S
R
I/O/Z
Serial port 0 transmit clock. CLKX0 is the serial shift clock for the serial port 0
transmitter.
S
R
1
I/O/Z
Data-receive. Serial port 0 receives serial data on DR0.
S
R
1
I/O/Z
Data-transmit output. Serial port 0 transmits serial data on DX0.
S
R
S
R
S
R
SERIAL PORT 0 SIGNALS
FSR0
1
I/O/Z
Frame-synchronization pulse for receive. The FSR0 pulse initiates the data-receive
process using DR0.
FSX0
1
I/O/Z
Frame-synchronization pulse for transmit. The FSX0 pulse initiates the data-transmit
process using DX0.
†
I = input, O = output, Z = high-impedance state
S = SHZ active, H = HOLD active, R = RESET active
§ Recommended decoupling. Four 0.1 µF for CV
DD and eight 0.1 µF for DVDD.
‡
6
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251-1443
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
Terminal Functions (Continued)
TERMINAL
NAME
QTY
CONDITIONS
WHEN
SIGNAL IS Z TYPE‡
TYPE†
DESCRIPTION
S
R
S
R
TIMER SIGNALS
TCLK0
1
I/O/Z
Timer clock 0. As an input, TCLK0 is used by timer 0 to count external pulses. As
an output, TCLK0 outputs pulses generated by timer 0.
TCLK1
1
I/O/Z
Timer clock 1. As an input, TCLK1 is used by timer 1 to count external pulses. As
an output, TCLK1 outputs pulses generated by timer 1.
H1
1
O/Z
External H1 clock
S
H3
1
O/Z
External H3 clock
S
SUPPLY AND OSCILLATOR SIGNALS
CVDD
8
I
+VDD. Dedicated 1.8-V power supply for the core CPU. All must be connected to
a common supply plane.§
DVDD
16
I
+VDD. Dedicated 3.3-V power supply for the I/O pins. All must be connected to a
common supply plane.§
VSS
18
I
Ground. All grounds must be connected to a common ground plane.
PLLVDD
1
I
Internally isolated PLL supply. Connect to CVDD (1.8 V)
PLLVSS
1
I
Internally isolated PLL ground. Connect to VSS
EXTCLK
1
I
External clock. Logic level compatible clock input. If the XIN/XOUT oscillator is
used, tie this pin to ground.
XOUT
1
O
Clock out. Output from the internal-crystal oscillator. If a crystal is not used, XOUT
should be left unconnected.
XIN
1
I
Clock in. Internal-oscillator input from a crystal. If EXTCLK is used, tie this pin to
ground.
CLKMD0,
CLKMD1
2
I
Clock mode select pins
RSV0 - RSV1
2
I
Reserved. Use individual pullups to DVDD.
EMU1- EMU0
2
I/O
TDI
1
I
Test data input
TDO
1
O
Test data output
TCK
1
I
Test clock
TMS
1
I
Test mode select
TRST
1
I
Test reset
JTAG EMULATION
Emulation pins 0 and 1, use individual pullups to DVDD
†
I = input, O = output, Z = high-impedance state
‡ S = SHZ active, H = HOLD active, R = RESET active
§ Recommended decoupling. Four 0.1 µF for CV
DD and eight 0.1 µF for DVDD.
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251-1443
7
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
functional block diagram
32
24
PAGE0
PDATA Bus
PAGE1
PAGE2
PAGE3
RDY
HOLD
HOLDA
STRB
R/W
D31- D0
A23- A0
PADDR Bus
32
24
ÉÉÉÉ
ÉÉÉÉ
ÉÉÉÉ
ÉÉÉÉ
RAM
Block 1
(1K × 32)
RAM
Block 0
(1K × 32)
Cache
(64 × 32)
24
RAM
Block 2
(16K × 32)
Boot
Loader
32
24
32
24
RAM
Block 3
(16K × 32)
32
24
32
MUX
MUX
DDATA Bus
DADDR1 Bus
DADDR2 Bus
DMADATA Bus
DMAADDR Bus
32
24
24
32
32
24
24
Peripheral Data Bus
DMA Controller
Global-Control
Register
Serial Port 0
MUX
DestinationAddress
Register
REG1
TransferCounter
Register
REG2
REG1
CPU1
32
32
40
40
Timer 0
40
32
Data-Transmit
Register
Global-Control
Register
ALU
40
Receive/Transmit
(R/X) Timer Register
Data-Receive
Register
32-Bit
Barrel
Shifter
Multiplier
40
CLKX0
FSR0
DR0
CLKR0
40
ExtendedPrecision
Registers
(R7-R0)
40
TCLK0
40
Timer-Period
Register
Timer-Counter
Register
Timer 1
DISP0, IR0, IR1
Global-Control
Register
ARAU0
BK
ARAU1
TCLK1
24
24
24
32
32
Auxiliary
Registers
(AR0- AR7)
Port Control
32
8
Other
Registers
(12)
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32
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Timer-Period
Register
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STRB-Control
Register
Peripheral Data Bus
CPU2
FSX0
DX0
Serial-Port-Control
Register
Peripheral Address Bus
Controller
JTAG Emulation
TCK
TMS
TRST
EXTCLK
XOUT
XIN
H1
H3
CLKMD(0,1)
Source-Address
Register
CPU1
REG2
PLL CLK
RSV(0,1)
SHZ
EDGEMODE
RESET
INT(3- 0)
IACK
MCBL/MP
XF(1,0)
TDI
TDO
EMU0
EMU1
IR
PC
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
memory map
0h
Reset, Interrupt, Trap Vector, and
Reserved Locations (64)
(External STRB Active)
0h
Reserved for Bootloader
Operations
03Fh
040h
External
STRB Active
(8M Words - 64 Words)
FFFh
1000h
Boot 1
400000h
Boot 2
7FFFFFh
800000h
7FFFFFh
800000h
RAM Block 2
(16K Words Internal)
803FFFh
804000h
RAM Block 2
(16K Words Internal)
803FFFh
804000h
RAM Block 3
(16K Words Internal)
807FFFh
808000h
External
STRB
Active
(8M Words 4K Words)
Peripheral Bus
Memory-Mapped Registers
(6K Words Internal)
8097FFh
809800h
RAM Block 3
(16K Words Internal)
807FFFh
808000h
Peripheral Bus
Memory-Mapped Registers
(6K Words Internal)
8097FFh
809800h
RAM Block 0
(1K Words Internal)
RAM Block 0
(1K Words Internal)
809BFFh
809C00h
809BFFh
809C00h
RAM Block 1
(1K Words Internal)
RAM Block 1
(1K Words Internal)
809FFFh
80A000h
FFFFFFh
External
STRB Active
(8M Words - 40K Words)
(a) Microprocessor Mode
User-Program Interrupt
and Trap Branch Table
809FC0h
809FC1h
809FFFh
80A000h
63 Words
FFF000h
Boot 3
FFFFFFh
External
STRB Active
(8M Words 40K Words)
(b) Microcomputer/Bootloader Mode
NOTE A: STRB is active over all external memory ranges. PAGE0 to PAGE3 are configured as external bus strobes. These are simple
decoded strobes that have no configuration registers and are active only during external bus activity over the following ranges:
Name
PAGE0
PAGE1
PAGE2
PAGE3
STRB
Active range
0000000h – 03FFFFFh
0400000h – 07FFFFFh
0800000h – 0BFFFFFh
0C00000h – 0FFFFFFh
0000000h – 0FFFFFFh
Figure 1. SM/SMJ320VC33 Memory Maps
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
memory map (continued)
00h
Reset
809FC1h
01h
INT0
809FC2h
02h
INT1
03h
INT2
04h
INT3
05h
XINT0
06h
RINT0
809FC6h
08h
Reserved
809FC8h
09h
TINT0
809FC9h
0Ah
TINT1
809FCAh
0Bh
DINT
809FCBh
0Ch
1Fh
Reserved
809FCCh
809FDFh
Reserved
20h
TRAP 0
809FE0h
TRAP 0
3Bh
TRAP 27
809FFBh
TRAP 27
3Ch
3Fh
Reserved
07h
INT0
INT1
809FC3h
INT2
809FC4h
INT3
809FC5h
XINT0
RINT0
809FC7h
Reserved
TINT0
TINT1
DINT
809FFCh
Reserved
809FFFh
(a) Microprocessor Mode
(b) Microcomputer/Bootloader Mode
Figure 2. Reset, Interrupt, and Trap Vector/Branches Memory-Map Locations
10
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
memory map (continued)
808000h
DMA Global Control
808004h
DMA Source Address
808006h
DMA Destination Address
808008h
DMA Transfer Counter
808020h
Timer 0 Global Control
808024h
Timer 0 Counter
808028h
Timer 0 Period Register
808030h
Timer 1 Global Control
808034h
Timer 1 Counter
808038h
Timer 1 Period Register
808040h
Serial Global Control
808042h
FSX/DX/CLKX Serial Port Control
808043h
FSR/DR/CLKR Serial Port Control
808044h
Serial R/X Timer Control
808045h
Serial R/X Timer Counter
808046h
Serial R/X Timer Period Register
808048h
Data-Transmit
80804Ch
Data-Receive
808064h
Primary-Bus Control
NOTE A: Shading denotes reserved address locations.
Figure 3. Peripheral Bus Memory-Mapped Registers
clock generator
The clock generator provides clocks to the VC33 device, and consists of an internal oscillator and a
phase-locked loop (PLL) circuit. The clock generator requires a reference clock input, which can be provided
by using a crystal resonator with the internal oscillator, or from an external clock source. The PLL circuit
generates the device clock by multiplying the reference clock frequency by a x5 scale factor, allowing use of
a clock source with a lower frequency than that of the CPU. The PLL is an adaptive circuit that, once
synchronized, locks onto and tracks an input clock signal.
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
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PLL and clock oscillator control
The clock mode control pins are decoded into four operational modes as shown in Figure 4. These modes
control clock divide ratios, oscillator, and PLL power (see Table 2).
When an external clock input or crystal is connected, the opposite unused input is simply grounded. An XOR
gate then passes one of the two signal sources to the PLL stage. This allows the direct injection of a clock
reference into EXTCLK, or 1-20 MHz crystals and ceramic resonators with the oscillator circuit. The two clock
sources include:
D A crystal oscillator circuit, where a crystal or ceramic resonator is connected across the XOUT and XIN pins
and EXTCLK is grounded.
D An external clock input, where an external clock source is directly connected to the EXTCLK pin, and XOUT
is left unconnected and XIN is grounded.
When the PLL is initially started, it enters a transitional mode during which the PLL acquires lock with the input
signal. Once the PLL is locked, it continues to track and maintain synchronization with the input signal. The PLL
is a simple x5 reference multiplier with bypass and power control.
The clock divider, under CPU control, reduces the clock reference by 1 (MAXSPEED), 1/16 (LOWPOWER), or
clock stop (IDLE2). Wake-up from the IDLE2 state is accomplished by a RESET or interrupt pin logic-low state.
A divide-by-two TMS320C31 equivalent mode of operation is also provided. In this case, the clock output
reference is further divided by two with clock synchronization being determined by the timing of RESET falling
relative to the present H1/H3 state.
Clock & Crystal OSC
PLL
Clock Divider
MAXSPEED/
LOWPOWER
EXTCLK
IDLE2
XOUT
M
U
X
XOR
S1
RF
X5 PLL
Á
XIN
Oscillator Enable
X1, 1/16, Off
1/2
M
U
X
CPU CLOCK
PLL PWR and Bypass
CLKMD0
SEL
C31 DIV2 Mode
CLKMD1
Figure 4. Clock Generation
Table 2. Clock Mode Select Pins
12
CLKMD0
CLKMD1
FEEDBACK
PLLPWR
0
0
Off
Off
1
0
1
On
Off
1/2
Oscillator enabled
1
0
On
Off
1
Oscillator enabled
1
1
On
On
5
2 mA @ 60 MHz, 1.8 V PLL power. Oscillator enabled
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
PLL and clock oscillator control (continued)
Typical crystals in the 8-30 MHz range have a series resistance of 25 Ω, which increases below 8 MHz. To
maintain proper filtering and phase relationships, Rd and Zout of the oscillator circuit should be 10x-40x that of
the crystal. A series compensation resistor (Rd), shown in Figure 5, is recommended when using lower
frequency crystals. The XOUT output, the square wave inverse of XIN, is then filtered by the XOUT output
impedance, C1 load capacitor, and Rd (if present). The crystal and C2 input load capacitor then refilters this
signal, resulting in a XIN signal that is 75-85% of the oscillator supply voltage.
NOTE: Some ceramic resonators are available in a low-cost, three-terminal package that includes C1 and C2
internally. Typically, ceramic resonators do not provide the frequency accuracy of crystals.
NOTE: Better PLL stability can be achieved using the optional power supply isolation circuit shown in Figure 5.
A similar filter can be used to isolate the PLLVSS, as shown in Figure 6. PLLVDD can also be directly connected
to CVDD.
Table 3. Typical Crystal Circuit Loading
†
FREQUENCY (MHz)
Rd (Ω)
C1 (pF)
C2 (pF)
CL† (pF)
RL† (Ω)
2
4.7k
18
18
12
200
5
2.2k
18
18
12
60
10
470
15
15
12
30
15
0
15
12
12
25
20
0
9
9
10
25
CL and RL are typical internal series load capacitance and resistance of the crystal.
XOUT
XIN
EXTCLK
PLLVSS
CVDD
PLLVDD
100 Ω
Rd
Crystal
C1
0.1 µF
C2
0.01 µF
Figure 5. Self-Oscillation Mode
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
PLL isolation
The internal PLL supplies can be directly connected to CVDD and VSS (0 Ω case) or fully isolated as shown in
Figure 6. The RC network prevents the PLL supplies from turning high frequency noise in the CVDD and VSS
supplies into jitter.
CVDD
0 -100 Ω
PLLVDD
0.1 µF
0.01 µF
PLLVSS
0 -100 Ω
VSS
Figure 6. PLL Isolation Circuit Diagram
clock and PLL considerations on initialization
On power up, the CPU clock divide mode can be in MAXSPEED, LOPOWER or IDLE2, or the PLL could be
in an undefined mode. RESET falling in the presence of a valid CPU clock is used to clear this state, after which
the device will synchronously terminate any external activity.
The 5x Fclkin PLL of the 320VC33 contains an 8-bit PLL-LOCK counter that will cause the PLL to output a
frequency of Fclkin/2 during the initial ramp. This counter, however, does not increment while RESET is low or
in the absence of an input clock. A minimum of 256 input clocks are required before the first falling edge of reset
for the PLL to output to clear this counter. The setup and behavior that is seen is as follows.
Power is applied to the DSP with RESET low and the input clock high or low. A clock is applied (RESET is still
low) and the PLL appears to lock on to the input clock, producing the expected x5 output frequency. RESET
is driven high and the PLL output immediately drops to Fclkin/2 for up to 256 input cycles or 128 of the Fclkin/2
output cycles. The PLL/CPU clock then switches to x5 mode.
The switch over is synchronous and does not create a clock glitch, so the only effect is that the CPU will run
slow for up to the first 128 cycles after reset goes high. Once the PLL has stabilized, the counter will remain
cleared and subsequent resets will not exhibit this condition.
power sequencing considerations
Though an internal ESD and CMOS latchup protection diode exists between CVDD and DVDD, it should not be
considered a current-carrying device on power up. An external Schottky diode should be used to prevent CVDD
from exceeding DVDD by more than 0.7 V. The effect of this diode during power up is that if CVDD is powered
up first, DVDD will follow by one diode drop even when the DVDD supply is not active.
Typical systems using LDOs of the same family type for both DVDD and CVDD will track each other during power
up. In most cases, this is acceptable; but if a high-impedance pin state is required on power up, the SHZ pin
can be used to asynchronously disable all outputs. RESET should not be used in this case since some signals
require an active clock for RESET to have an effect and the clock may not yet be active. The internal core logic
becomes functional at approximately 0.8 V while the external pin IO becomes active at about 1.5 V.
14
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
EDGEMODE
When EDGEMODE = 1, a sampled digital delay line is decoded to generate a pulse on the falling edge of the
interrupt pin. To ensure interrupt recognition, input signal logic-high and logic-low states must be held longer
than the synchronizer delay of one CPU clock cycle. Holding these inputs to no less than two cycles in both the
logic-low and logic-high states is sufficient.
When EDGEMODE = 0, a logic-low interrupt pin will continually set the corresponding interrupt flag. The CPU
or DMA can clear this flag within two cycles of it being set. This is the maximum interrupt width that can be applied
if only one interrupt is to be recognized. The CPU can manually clear IF bits within an interrupt service routine
(ISR), effectively lengthening the maximum ISR width.
After reset, EDGEMODE is temporarily disabled, allowing logic-low INT pins to be detected for bootload
operation.
Delay
RESET
EDGEMODE
INTn
D Q
D Q
D Q
D Q
D Q
S
Q
IF Bit
R
CPU Reset
H1
CPU Set
H3
Figure 7. EDGEMODE and Interrupt Flag CIrcuit
reset operation
When RESET is applied, the CPU attempts to safely exit any pending read or write operations that may be in
progress. This can take as much as 10 CPU cycles, after which, the address, data, and control pins will be in
an inactive or high-impedance state.
When both RESET and SHZ are applied, the device will immediately enter the reset state with the pins held in
high-impedance mode. SHZ should then be disabled at least 10 CPU cycles before RESET is set high. SHZ
can be used during power-up sequencing to prevent undefined address, data, and control pins, avoiding system
conflicts.
PAGE0 - PAGE3 select lines
To facilitate simpler and higher speed connection to external devices, the SM/SMJ320VC33 includes four
predecoded select pins that have the same timings as STRB. These pins are decoded from A22, A23, and STRB
and are active only during external accesses over the ranges shown in Table 4. All external bus accesses are
controlled by a single bus control register.
Table 4. PAGE0 - PAGE3 Ranges
START
END
PAGE0
0x000000
0x3FFFFF
PAGE1
0x400000
0x7FFFFF
PAGE2
0x800000
0xBFFFFF
PAGE3
0xC00000
0xFFFFFF
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DIGITAL SIGNAL PROCESSOR
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using external logic with the READY pin
The key to designing external wait-state logic is the internal bus control register and associated internal logic
that logically combines the external READY pin with the much faster on-chip bus control logic. This essentially
allows slow external logic to interact with the bus while easily meeting the READY input timings. It is also relevant
to mention that the combined ready signals are sampled on the rising edge of the internal H1 clock. Please refer
to Figure 8 for the following examples.
example 1
A simple 0 or WTCNT wait-state decoder can be created by simply tying an address line back to the READY
pin and selecting the AND option. When the tied back address is low, the bus will run with 0 wait states. When
the tied back address is high, the bus will be controlled by the internal wait-state counter.
By enabling the bank compare logic, proper operation is further ensured by inserting a null cycle before a read
on the next bank is performed (writes are not pre-extended). This extra time can also be used by external logic
to affect the feedback path.
example 2
An N-WTCNT minimum wait-state decoder can also be created by tying back an address line to READY and
logically ORing it with the internal bank compare and wait count signals. When the address pin is low, bus timing
is determined by the internal WTCNT and BNKCMP settings. When the address line is high, the bus can run
no faster than the WTCNT counter and will be extended as long as READY is held high.
A23
A22
PAGE_0
PAGE_1
PAGE_2
PAGE_3
Decode
Device
Enable
Pins
Bus_Enable_Strobe,
0 = Active
STRB Pin
0 = Bus Idle
To C31 Style
Decoder
(C31 Compatibility)
H3
External Bus Interface
Abus
D Q
N-Bit
Bank
Compare
Q
BUS_READY
Abus_old
H3
R
N_Wait
Counter
1
D
H1
2
3
0
R/W
R/W Pin
Figure 8. Internal Ready Logic, Simplified Diagram
16
READY Pin
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DIGITAL SIGNAL PROCESSOR
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example 2 (continued)
Table 5. MUX Select (Bus Control Register Bits 4 and 3)
BIT 4
BIT 3
0
0
Ignore internal wait counter and use only external READY
RESULTS
0
1
Use only internal wait counter and ignore ready pin
1
0
Logically AND internal wait counter with ready pin
1
1
Logically OR internal wait counter with ready pin (reset default)
posted writes
External writes are effectively “posted” to the bus, which then acts like an output latch until the write completes.
Therefore, if the application code is executing internally, it can perform a very slow external write with no penalty
since the bus acts like it has a one-level-deep write FIFO.
data bus I/O buffer
The circuit shown in Figure 9 is incorporated into each data pin to lightly “hold” the last driven value on the data
bus pins when the DSP or an external device is not actively driving the bus. Each bus keeper is built from a
three-state driver with nominal 15 kΩ output resistance which is fed back to the input in a positive feedback
configuration. The resistance isolated driver then pulls the output in one direction or the other keeping the last
driven value. This circuit is enabled in all functional modes and is only disabled when SHZ is pulled low.
R/W
30 Ω
External Data
Bus Pin
Internal
Data Bus
15 kΩ
SHZ
Bus keeper
Figure 9. Bus Keeper Circuit
For an external device to change the state of these pins, it must be able to drive a small dc current until the driver
threshold is crossed. At the crossover point, the driver changes state, agreeing with the external driver and
assisting the change. The voltage threshold of the bus keeper is approximately at 50% of the DVDD supply
voltage. The typical output impedance of 30 Ω for all SM/SMJ320VC33 I/O pins is easily capable of meeting
this requirement.
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
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bootloader operation
When MCBL/MP = 1, an internal ROM is decoded into the address range of 0x000000-0x000FFF. Therefore,
when reset occurs, execution begins within the internal ROM program and vector space. No external activity
will be evident until one of the boot options is enabled. These options are enabled by pulling an external interrupt
pin low, which the boot-load software then detects, causing a particular routine to be executed (see Table 6).
Table 6. INT0 - INT3 Sources
ACTIVE INTERRUPT
ADDRESS/SOURCE WHERE BOOT DATA IS
READ FROM
DATA FORMAT
INT0
0x001000
8, 16, or 32-bit width
INT1
0x400000
8, 16, or 32-bit width
INT2
0xFFF000
8, 16, or 32-bit width
INT3
Serial Port
32-bit, external clock, and frame synch
When MCBL/MP = 1, the reset and interrupt vectors are hard-coded within the internal ROM. Since this is a
read-only device, these vectors cannot be modified. To enable user-defined interrupt routines, the internal
vectors contain fixed values that point to an internal section of SRAM beginning at 0x809FC1. Code execution
begins at these locations so it is important to place branch instructions (to the interrupt routine) at these locations
and not vectors.
The bootloader program requires a small stack space for calls and returns. Two SRAM locations at 0x809800
and 0x809801 are used for this stack. Data should not be boot loaded into these locations as this will corrupt
the bootloader program run-time stack. After the boot-load operation is complete, a program can reclaim these
locations. The simplest solution is to begin a program stack or uninitialized data section at 0x809800.
For additional detail on bootloader operation including the bootloader source code, see the TMS320C3x User’s
Guide (literature number SPRU031).
A bit I/O line or external logic can be used to safely disable the MCBL mode after bootloading is complete.
However, to ensure proper operation, the CPU should not be currently executing code or using external data
as the change takes place. In the following example, the XF0 pin is 3-state on reset, which allows the pullup
resistor to place the DSP in MCBL mode. The following code, placed at the beginning of an application then
causes the XF0 pin to become an active-logic-low output, changing the DSP mode to MP. The cache-enable
and RPTS instructions are used since they cause the LDI instruction to be executed multiple times even though
it has been fetched only once (before the mode change). In other words, the RPTS instruction acts as a
one-level-deep program cache for externally executed code. If the application code is to be executed from
internal RAM, no special provisions are needed.
LDI
8000h,ST
; Enable the cache
RPTS
4
; RPTS will fetch the following opcode 1 time
LDI
2h, IOF
; Drive MCBL/MP=0 for several cycles allowing
; the pipeline to clear
RESET
RESET
SM/SMJ320VC33
DVDD
RPU
XF0
MCBL/MP
Figure 10. Changing Bootload Select Pin
18
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DIGITAL SIGNAL PROCESSOR
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JTAG emulation
Though the 320VC33 contains a JTAG debug port which allows multiple JTAG enabled chips to be
daisy-chained, boundary scan of the pins is not supported. If the pin scan path is selected, it will be routed
through a null register with a length of one. For additional information concerning the emulation interface, see
JTAG/MPSD Emulation Technical Reference (literature number SPDU079).
designing a target system emulator connector (14-pin header)
JTAG target devices support emulation through a dedicated emulation port. This port is a superset of the test
access port standard and is accessed by the emulator. To communicate with the emulator, the target system
must have a 14-pin header (two rows of seven pins) with the connections that are shown in Figure 11. Table 7
describes the emulation signals.
TMS
1
2
TRST
TDI
3
4
GND
PD (VCC)
5
6
no pin (key)†
TDO
7
8
GND
TCK_RET
†
9
10
GND
TCK
11
12
GND
EMU0
13
14
EMU1
Header Dimensions:
Pin-to-pin spacing, 0.100 in. (X,Y)
Pin width, 0.025-in. square post
Pin length, 0.235-in. nominal
While the corresponding female position on the cable connector is plugged to prevent improper
connection, the cable lead for pin 6 is present in the cable and is grounded, as shown in the
schematics and wiring diagrams in this document.
Figure 11. 14-Pin Header Signals and Header Dimensions
Table 7. 14-Pin Header Signal Descriptions
SIGNAL
DESCRIPTION
EMULATOR†
STATE
TARGET†
STATE
I
TMS‡
Test mode select
O
TDI
Test data input
O
I
TDO
Test data output
I
O
TCK
Test clock. TCK is a 10.368-MHz clock source from the emulation cable pod.
This signal can be used to drive the system test clock
O
I
TRST§
Test reset
O
I
EMU0‡¶
Emulation pin 0
I
I/O
EMU1‡¶
Emulation pin 1
I
I/O
PD(VCC)
Presence detect. Indicates that the emulation cable is connected and that the
target is powered up. PD should be tied to VCC in the target system.
I
O
TCK_RET
Test clock return. Test clock input to the emulator. May be a buffered or unbuffered version of TCK.
I
O
GND
Ground
†
I = input; O = output
Use 1-50K pullups for TMS, EMU0 and EMU1.
§ Use 1-50K pulldown for TRST. Do not use pullup resistors on TRST: it has an internal pulldown device. In a low-noise environment, TRST can
be left floating. In a high-noise environment, an additional pulldown resistor may be needed. (The size of this resistor should be based on electrical
current considerations.)
¶ EMU0 and EMU1 are I/O drivers configured as open-drain (open-collector) drivers. They are used as bidirectional signals for emulation global
start and stop.
‡
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DIGITAL SIGNAL PROCESSOR
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designing a target system emulator connector (14-pin header) (continued)
Although other headers can be used, recommended parts include:
straight header, unshrouded
DuPont Connector Systems
part numbers:
65610-114
65611-1 14
67996-114
67997-114
JTAG emulator cable pod logic
Figure 12 shows a portion of the emulator cable pod. The functional features of the pod are as follows:
D Signals TDO and TCK_RET can be parallel-terminated inside the pod if required by the application. By
default, these signals are not terminated.
D Signal TCK is driven with a 74LVT240 device. Because of the high-current drive (32 mA IOL/IOH), this signal
can be parallel-terminated. If TCK is tied to TCK_RET, the parallel terminator in the pod can be used.
D Signals TMS and TDI can be generated from the falling edge of TCK_RET, according to the bus slave device
timing rules.
D Signals TMS and TDI are series-terminated to reduce signal reflections.
D A 10.368-MHz test clock source is provided. Another test clock can be used for greater flexibility.
+5 V
180 Ω
74F175
270 Ω
Q
JP1
Q
D
TDO (Pin 7)
74LVT240
10.368 MHz
Y
Y
GND (Pins 4,6,8,10,12)
A
33 Ω
33 Ω
TMS (Pin 1)
Y
TDI (Pin 3)
Y
EMU0 (Pin 13)
74AS1034
TCK (Pin 11){
EMU1 (Pin 14)
+5 V
180 Ω
270 Ω
TRST (Pin 2)
74AS1004
JP2
TCK_RET (Pin 9){
PD(VCC) (Pin 5)
100 Ω
†
RESIN
TL7705A
The emulator pod uses TCK_RET as its clock source for internal synchronization. TCK is provided as an optional target system
test clock source.
Figure 12. JTAG Emulator Cable Pod Interface
20
POST OFFICE BOX 1443
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
device and development support tool nomenclature
To designate the stages in the product development cycle, TI assigns prefixes to the part numbers of all
TMS320 DSP family devices and support tools. Each TMS320 DSP member has one of three prefixes: TMX,
TMP, or TMS. Texas Instruments recommends two of three possible prefix designators for its support tools:
TMDX and TMDS. These prefixes represent evolutionary stages of product development from engineering
prototypes (TMX/TMDX) through fully qualified production devices/tools (TMS/TMDS). This development flow
is defined below.
Device development evolutionary flow:
SMX
Experimental device that is not necessarily representative of the final device’s electrical
specifications
TMP
Final silicon die that conforms to the device’s electrical specifications but has not completed
quality and reliability verification
SM/SMJ
Fully-qualified production device
Support tool development evolutionary flow:
TMDX
Development support product that has not yet completed Texas Instruments internal qualification
testing.
TMDS
Fully qualified development support product
TMX and TMP devices and TMDX development support tools are shipped against the following disclaimer:
“Developmental product is intended for internal evaluation purposes.”
TMS devices and TMDS development support tools have been characterized fully, and the quality and reliability
of the device has been demonstrated fully. TI’s standard warranty applies.
Predictions show that prototype devices (TMX or TMP) have a greater failure rate than the standard production
devices. Texas Instruments recommends that these devices not be used in any production system because their
expected end-use failure rate still is undefined. Only qualified production devices are to be used.
TI device nomenclature also includes a suffix with the device family name. This suffix indicates the package type
(for example, HFG, GNM, or GNL) and temperature range (for example, M). Figure 13 provides a legend for
reading the complete device name for any TMS320 DSP family member.
TMS320 is a trademark of Texas Instruments.
POST OFFICE BOX 1443
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21
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
device and development support tool nomenclature (continued)
SMJ
PREFIX
SMX =
TMP =
TMS =
SMJ =
SMQ=
SM =
320
VC 33 GNM
experimental device
prototype device
qualified device
MIL-PRF-38535 (QML)
QML Plastic device
Commericial processing
M
150
SPEED
150 = 150 MFLOPS
TEMPERATURE RANGE
M = Military
DEVICE FAMILY
320 = TMS320 Family
PACKAGE TYPE†
HFG = 164-pin ceramic QFP
GNL = 144-pin ceramic BGA, hermetic
GNM = 144-pin ceramic BGA, non-hermetic
TECHNOLOGY
C = CMOS
E = CMOS EPROM
F = CMOS Flash EEPROM
LC = Low-Voltage CMOS (3.3 V)
VC = Low-Voltage CMOS [3 V (2.5 V
or 1.8 V core)]
UC= Ultra Low-Voltage CMOS [1.8 V
(1.5 V core)]
DEVICE
3x DSP:
30
31
32
33
4x DSP:
40
44
6x DSP:
6201 6201
6701 6211
†
QFP = Quad Flat Package
LQFP = Low-Profile Quad Flat Package
BGA = Ball Grid Array
Figure 13. TMS320 DSP Device Nomenclature
22
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
absolute maximum ratings over specified temperature range (unless otherwise noted)†
Supply voltage range, DVDD‡ . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . - 0.3 V to 4 V
Supply voltage range, CVDD‡ . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . - 0.3 V to 2.4 V
Input voltage range, VI§ . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -1 V to 4.6 V
Output voltage range, VO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . - 0.3 V to 4.6 V
Continuous power dissipation (worst case)¶ . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 500 mW
Operating case temperature range, TC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -55 °C to 125°C
Storage temperature range, Tstg . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . - 55°C to 150°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.
‡ All voltage values are with respect to V .
SS
§ Absolute dc input level should not exceed the DV
DD or VSS supply rails by more than 0.3 V. An instantaneous low current pulse of < 2 ns,
< 10 mA, and < 1 V amplitude is permissable.
¶ Actual operating power is much lower. This value was obtained under specially produced worst-case test conditions for the SM/SMJ320VC33,
which are not sustained during normal device operation. These conditions consist of continuous parallel writes of a checkerboard pattern to the
external data and address buses at the maximum possible rate with a capacitive load of 30 pF. See normal (ICC) current specification in the
electrical characteristics table and also read TMS320C3x General-Purpose Applications (literature number SPRU194).
recommended operating conditions‡#||
MIN
NOM
MAX
UNIT
CVDD
Supply voltage for the core CPUk
1.71
1.8
1.89
V
DVDD
Supply voltage for the I/O pinsh
3.14
3.3
3.46
V
VSS
Supply ground
VIH
High-level input voltage
0.7 x DVDD
DVDD + 0.3§
VIL
Low-level input voltage
-0.3 §
0.3 x DVDD
IOH
High-level output current
IOL
Low-level output current
TC
Operating case temperature
CL
Capacitive load per output pin
0
-55
V
V
V
4
mA
4
mA
125
°C
30
pF
‡
All voltage values are with respect to VSS.
Absolute dc input level should not exceed the DVDD or VSS supply rails by more than 0.3 V. An instantaneous low current pulse of < 2 ns, < 10 mA,
and < 1 V amplitude is permissable.
# All inputs and I/O pins are configured as inputs.
|| All input and I/O pins use a Schmidt hysteresis inputs except SHZ and D0-D31. Hysteresis is approximately 10% of DV
DD and is centered at
0.5 x DVDD.
k CVDD should not exceed DVDD by more than 0.7 V. (Use a Schottky clamp diode between these supplies.)
h DVDD should not exceed CVDD by more than 2.5 V.
§
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23
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
electrical characteristics over recommended ranges of supply voltage (unless otherwise noted)†
TEST CONDITIONS‡
PARAMETER
VOH
High-level output voltage
DVDD = MIN,
IOH = MAX
VOL
Low-level output voltage
DVDD = MIN,
IOL = MAX
IZ
High-impedance current
TC = 25°C,
DVDD = MAX
II
Input current
TC = 25°C,
VI = VSS to DVDD
IIPU
Input current (with internal pullup)
Inputs with internal pullups¶
IIPD
Input current (with internal pulldown)
Inputs with internal pulldowns¶
pullup#
MIN
TYP§
MAX
2.4
Bus keeper opposes until conditions match
UNIT
V
0.4
V
-5
+5
µA
-5
+5
µA
-600
10
µA
600
-10
µA
-600
10
µA
600
-10
µA
IBKU
Input current (with bus keeper)
IBKD
Input current (with bus keeper) pulldown#
IDDD
Supply current, pins||k
TC = 25°C, fx = 75 MHz
DVDD = MAX
25
260
mA
IDDC
Supply current, core CPU||k
TC = 25°C, fx = 75 MHz
CVDD = MAX
60
215
mA
IDD
IDLE2, Supply current, IDDD plus IDDC
PLL enabled, oscillator enabled
2
PLL disabled, oscillator enabled
500
PLL disabled, oscillator disabled, FCLK = 0
Ci
Input capacitance
Co
Output capacitance
mA
µA
A
50
All inputs except XIN
10*
XIN
10*
10*
pF
pF
* Not production tested
† All voltage values are with respect to V .
SS
‡ For test conditions shown as MIN, MAX, or NOM, use the appropriate value specified in the recommended operating conditions table.
§ For VC33, all typical values are at DV
DD = 3.3, CVDD = 1.8 V, TC (case temperature) = 25°C.
¶ Pins with internal pullup devices: TDI, TCK, and TMS. Pin with internal pulldown device: TRST.
# Pins D0-D31 include internal bus keepers that maintain valid logic levels when the bus is not driven (see Figure 9).
|| Actual operating current is less than this maximum value. This value was obtained under specially produced worst-case test conditions, which
are not sustained during normal device operation. These conditions consist of continuous parallel writes of a checkerboard pattern at the
maximum rate possible. See TMS320C3x General-Purpose Applications (literature number SPRU194).
k fx is the PLL output clock frequency.
PARAMETER MEASUREMENT INFORMATION
IOL
50 Ω
Tester Pin
Electronics
VLoad
CT
Output
Under
Test
IOH
Where:
IOL
= 4 mA (all outputs) for dc levels test.
IO and IOH are adjusted during ac timing analysis to achieve an ac termination of 50 Ω
VLOAD = DVDD/2
CT
= 40-pF typical load-circuit capacitance
Figure 14. Test Load Circuit
24
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
PARAMETER MEASUREMENT INFORMATION
timing parameter symbology
Timing parameter symbols used herein were created in accordance with JEDEC Standard 100. To shorten the
symbols, some of the pin names and other related terminology have been abbreviated as follows, unless
otherwise noted:
Lowercase subscripts and their meanings
Letters and symbols and their meanings
a
access time
H
High
c
cycle time (period)
L
Low
d
delay time
V
Valid
dis
disable time
Z
High Impedance
en
enable time
f
fall time
h
hold time
r
rise time
su
setup time
t
transition time
v
valid time
w
pulse duration (width)
x
unknown, changing, or don’t care level
Additional symbols and their meaning
A
Address lines (A23- A0)
H
H1 and H3
ASYNCH
Asynchronous reset signals (XF0, XF1, CLKX0, DX0,
FSX0, CLKR0, DR0, FSR0, TCLK0, and TCLK1)
HOLD
HOLD
CLKX
CLKX0
HOLDA
HOLDA
CLKR
CLKR0
IACK
IACK
CONTROL
Control signals
INT
INT3- INT0
D
Data lines (D31- D0)
PAGE
PAGE0- PAGE3
DR
DR
RDY
RDY
DX
DX
RW
R/W
EXTCLK
EXTCLK
RW
R/W
FS
FSX/R
RESET
RESET
FSX
FSX0
S
STRB
FSR
FSR0
SCK
CLKX/R
GPI
General-purpose input
SHZ
SHZ
GPIO
General-purpose input/output; peripheral pin (CLKX0,
CLKR0, DX0, DR0, FSX0, FSR0, TCLK0, and TCLK1)
TCLK
TCLK0, TCLK1, or TCLKx
GPO
General-purpose output
XF
XF0, XF1, or XFx
H1
H1
XF0
XF0
H3
H3
XF1
XF1
XIN
XIN
POST OFFICE BOX 1443
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25
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
phase-locked loop (PLL) circuit timing
phase-locked loop characteristics using EXTCLK or on-chip crystal oscillator†
MIN
MAX
UNIT
Fpllin
Frequency range, PLL input
PARAMETER
5*
15*
MHz
Fpllout
Frequency range, PLL output
25*
75*
MHz
Ipll
PLL current, CVDD supply
2*
mA
Ppll
PLL power, CVDD supply
5*
mW
PLLdc
PLL output duty cycle at H1
PLLJ
PLLLOCK
45*
55*
%
PLL output jitter, Fpllout = 25 MHz
400*
ps
PLL lock time in input cycles
1000
cycles
* Not production tested
† Duty cycle is defined as 100*t /(t +t )%
1 1 2
To ensure clean internal clock references, the minimal low and high pulse durations must be maintained. At high
frequencies, this may require a fast rise and fall time as well as a tightly controlled duty cycle. At lower
frequencies, these requirements are less restrictive when in x1 and x0.5 modes. The PLL, however, must have
an input duty cycle of between 40% and 60% for proper operation.
26
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
clock circuit timing
The following table defines the timing parameters for the clock circuit signals.
circuit parameters for on-chip crystal oscillator† (see Figure 15)
PARAMETER
MIN
TYP
MAX
UNIT
20*
MHz
50
60*
%VO
300
500*
kΩ
VO
Oscillator internal supply voltage
CVDD
FO
Fundamental mode frequency range
Vbias
DC bias point (input threshold)
40*
Rfbk
Feedback resistance
100*
Rout
Small signal ac output impedance
250*
500
1000*
Vxoutac
The ac output voltage with test crystal‡
85
%VO
Vxinac
The ac input voltage with test crystal‡
85
%VO
Vxoutl
Vxin = Vxinh, Ixout = 0, FO=0 (logic input)
VSS - 0.1*
VSS + 0.3*
V
Vxouth
Vxin = Vxinl, Ixout = 0, FO=0 (logic input)
CVDD - 0.3*
CVDD + 0.1*
V
Vinl
When used for logic level input, oscillator enabled
-0.3*
0.2 x VO*
V
Vinh
When used for logic level input, oscillator enabled
0.8 x VO*
DVDD + 0.3*
V
Vxinh
When used for logic level input, oscillator disabled
0.7 x DVDD
DVDD + 0.3
V
Cxout
XOUT internal load capacitance
2*
3
5*
pF
Cxin
XIN internal load capacitance
2*
3
5*
pF
td(XIN-H1)
Delay time, XIN to H1 x1 and x0.5 modes
2
5.5
8
ns
Iinl
Input current, feedback enabled, Vil = 0
50*
µA
Iinh
Input current, feedback enabled, Vil = Vih
-50*
µA
1*
V
Ω
* Not production tested
† This circuit is intended for series resonant fundamental mode operation.
‡ Signal amplitude is dependent on the crystal and load used.
Rd
XOUT
ROUT
CXOUT
C1
Rfbk
Crystal
VO
XIN
CXIN
To internal
clock generator
C2
NOTE A: See Table 3 for value of Rd.
Figure 15. On-Chip Oscillator Circuit
POST OFFICE BOX 1443
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27
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
clock circuit timing (continued)
The following tables define the timing requirements and switching characteristics for EXTCLK.
timing requirements for EXTCLK, all modes (see Figure 16 and Figure 17)
MIN
tr(EXTCLK)
Rise time,
time EXTCLK
tf(EXTCLK)
Fall time,
time EXTCLK
tw(EXTCLKL)
tw(EXTCLKH)
tdc(EXTCLK)
tc(EXTCLK)
Fext
Pulse duration, EXTCLK low
Pulse duration, EXTCLK high
Duty cycle, EXTCLK [tw(EXTCLKH) / tc(H)]
Cycle time, EXTCLK
Frequency range, 1/tc(EXTCLK)
MAX
F = Fmax, x0.5 and x1 modes
1*
F < Fmax
4*
F = Fmax, x0.5 and x1 modes
1*
F < Fmax
4*
x5 mode
21*
x1 mode
6*
x0.5 mode
4*
x5 mode
21*
x1 mode
5*
x0.5 mode
4*
x5 PLL mode
40*
x1 and x0.5 modes, F = max
45
55
x1 and x0.5 modes, F = 0 Hz
0*
100*
x5 mode
66.7*
200*
x1 mode
13.3
x0.5 mode
10*
x5 mode
5*
x1 mode
0
75
x0.5 mode
0*
100*
UNIT
ns
ns
ns
ns
60*
%
ns
15*
MHz
* Not production tested
switching characteristics for EXTCLK over recommended operating conditions, all modes
(see Figure 16 and Figure 17)
PARAMETER
Vmid
MIN
Mid-level, used to measure duty cycle
TYP
MAX
0.5 x DVDD
UNIT
V
x1 mode
2*
4.5
7*
x0.5 mode
2*
4.5
7*
td(EXTCLK-H)
Delay time, EXTCLK to H1 and
H3
tr(H)
Rise time, H1 and H3
3*
ns
tf(H)
Fall time, H1 and H3
3*
ns
td(HL-HH)
Delay time, from H1 low to H3 high or from H3 low to H1 high
2*
ns
-1.5*
x5 PLL mode
tc(H)
Cycle time, H1 and H3
28
1/(5 x fext)
x1 mode
1/fext
x0.5 mode
2/fext
* Not production tested
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251-1443
ns
ns
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
clock circuit timing (continued)
tc(EXTCLK)
tr(EXTCLK)
tw(EXTCLKH)
EXTCLK
tw(EXTCLKL)
tf(EXTCLK)
tc(H)
H3
td(EXTCLK-H)
tf(H)
td(EXTCLK-H)
H1
tr(H)
Figure 16. Divide-By-Two Mode
tc(EXTCLK)
tr(EXTCLK)
tf(EXTCLK)
tw(EXTCLKH)
EXTCLK
tw(EXTCLKL)
td(EXTCLK-H)
td(EXTCLK-H)
H3
tc(H)
td(HL-HH)
H1
NOTE A: EXTCLK is held low.
Figure 17. Divide-By-One Mode
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29
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
memory read/write timing
The following tables define memory read/write timing parameters for STRB.
timing requirements for memory read/write† (see Figure 18, Figure 19, and Figure 20)
MIN
MAX
UNIT
tsu(D-H1L)R
Setup time, Data before H1 low (read)
5*
ns
th(H1L-D)R
Hold time, Data after H1 low (read)
-1*
ns
tsu(RDY-H1H)
Setup time, RDY before H1 high
5
ns
th(H1H-RDY)
Hold time, RDY after H1 high
td(A-RDY)
Delay time, Address valid to RDY
tv(A-D)
Valid time,
time Data valid after address PAGEx
PAGEx, or STRB valid
-1*
ns
P - 6*‡
ns
6*
ns
tc(H) + 6*
ns
0 wait state, CL = 30 pF
1 wait state
* Not production tested
† These timings assume a similar loading of 30 pF on all pins.
‡P=t
c(H)/2 (when duty cycle equals 50%).
switching characteristics over recommended operating conditions for memory read/write†
(see Figure 18, Figure 19, and Figure 20)
PARAMETER
MIN
MAX
UNIT
td(H1L-SL)
Delay time, H1 low to STRB low
-1*
3
ns
td(H1L-SH)
Delay time, H1 low to STRB high
-1*
3
ns
td(H1H-RWL)W
Delay time, H1 high to R/W low (write)
-1*
3
ns
td(H1L-A)
Delay time, H1 low to address valid
-1*
3
ns
td(H1H-RWH)W
Delay time, H1 high to R/W high (write)
-1*
3
ns
td(H1H-A)W
Delay time, H1 high to address valid on back-to-back write cycles (write)
-1*
3*
ns
tv(H1L-D)W
Valid time, Data after H1 low (write)
5
ns
th(H1H-D)W
Hold time, Data after H1 high (write)
5
ns
0*
* Not production tested
† These timings assume a similar loading of 30 pF on all pins.
Output load characteristics for high-speed and low-speed (low-noise) output buffers are shown in Figure 18.
High-speed buffers are used on A0 - A23, PAGE0 - PAGE3, H1, H3, STRB, and R/W. All other outputs use the
low-speed, (low-noise) output buffer.
Low-Noise Buffer
0.05 ns/pF
5
4
High-Speed Buffer
0.04 ns/pF
3
HIGH
SPEED
LOW
NOISE
0 pF
2.0
2.8
15 pF
2.6
3.4
LOAD
30 pF
3.2
4.4
50 pF
4.0
5.25
2
Output
Delay (ns)
1
10
CLmax = 30 pF
20
30
40
50
Load Capacitance (pF)
Figure 18. Output Load Characteristics, Buffer Only
30
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251-1443
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
memory read/write timing (continued)
H3
H1
td(H1L-SL)
td(H1L-SH)
PAGEx, STRB
td(H1L-A)
R/W
tv(A-D)
td(H1H-RWL)W
A[23:0]
tsu(D-H1L)R
th(H1L-D)R
td(A-RDY)
D[31:0]
tsu(RDY-H1H)
th(H1H-RDY)
RDY
NOTE A: STRB remains low during back-to-back read operations.
Figure 19. Timing for Memory (STRB = 0 and PAGEx = 0) Read
H3
H1
td(H1L-SH)
td(H1L-SL)
PAGEx, STRB
td(H1H-RWL)W
td(H1H-RWH)W
R/W
td(H1L-A)
td(H1H-A)W
A[23:0]
th(H1H-D)W
tv(H1L-D)W
D[31:0]
th(H1H-RDY)
tsu(RDY-H1H)
RDY
Figure 20. Timing for Memory (STRB = 0 and PAGEx = 0) Write
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31
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
XF0 and XF1 timing when executing LDFI or LDII
The following tables define the timing parameters for XF0 and XF1 during execution of LDFI or LDII.
timing requirements for XF0 and XF1 when executing LDFI or LDII (see Figure 21)
MIN
MAX
UNIT
tsu(XF1-H1L)
Setup time, XF1 before H1 low
4*
ns
th(H1L-XF1)
Hold time, XF1 after H1 low
0*
ns
* Not production tested
switching characteristics over recommended operating conditions for XF0 and XF1 when executing
LDFI or LDII (see Figure 21)
PARAMETER
td(H3H-XF0L)
MIN
Delay time, H3 high to XF0 low
Fetch
LDFI or LDII
Decode
Read
Execute
H3
H1
PAGEx, STRB
R/W
A[23:0]
D[31:0]
RDY
td(H3H-XF0L)
XF0
tsu(XF1-H1L)
th(H1L-XF1)
XF1
Figure 21. Timing for XF0 and XF1 When Executing LDFI or LDII
32
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MAX
UNIT
3
ns
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
XF0 timing when executing STFI and STII†
The following table defines the timing parameters for the XF0 pin during execution of STFI or STII.
switching characteristics over recommended operating conditions for XF0 when executing STFI
or STII (see Figure 22)
PARAMETER
td(H3H-XF0H)
†
Delay time, H3 high to XF0
MIN
high†
MAX
UNIT
3
ns
XF0 is always set high at the beginning of the execute phase of the interlock-store instruction. When no pipeline conflicts occur, the address of
the store is also driven at the beginning of the execute phase of the interlock-store instruction. However, if a pipeline conflict prevents the store
from executing, the address of the store will not be driven until the store can execute.
Fetch
STFI or STII
Decode
Read
Execute
H3
H1
PAGEx, STRB
R/W
A[23:0]
D[31:0]
RDY
td(H3H-XF0H)
XF0
Figure 22. Timing for XF0 When Executing an STFI or STII
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
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XF0 and XF1 timing when executing SIGI
The following tables define the timing parameters for the XF0 and XF1 pins during execution of SIGI.
timing requirements for XF0 and XF1 when executing SIGI (see Figure 23)
MIN
MAX
UNIT
tsu(XF1-H1L)
Setup time, XF1 before H1 low
4*
ns
th(H1L-XF1)
Hold time, XF1 after H1 low
0*
ns
* Not production tested
switching characteristics over recommended operating conditions for XF0 and XF1 when executing
SIGI (see Figure 23)
MAX
UNIT
td(H3H-XF0L)
Delay time, H3 high to XF0 low
PARAMETER
3
ns
td(H3H-XF0H)
Delay time, H3 high to XF0 high
3
ns
Fetch
SIGI
MIN
Decode
Read
Execute
H3
H1
tsu(XF1-H1L)
td(H3H-XF0L)
td(H3H-XF0H)
XF0
th(H1L-XF1)
XF1
Figure 23. Timing for XF0 and XF1 When Executing SIGI
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
loading when XF is configured as an output
The following table defines the timing parameter for loading the XF register when the XFx pin is configured as
an output.
switching characteristics over recommended operating conditions for loading the XF register when
configured as an output pin (see Figure 24)
PARAMETER
tv(H3H-XF)
MIN
Valid time, XFx after H3 high
Fetch Load
Instruction
Decode
Read
MAX
UNIT
3
ns
Execute
H3
H1
OUTXFx Bit
(see Note A)
1 or 0
tv(H3H-XF)
XFx
NOTE A: OUTXFx represents either bit 2 or 6 of the IOF register.
Figure 24. Timing for Loading XF Register When Configured as an Output Pin
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
changing XFx from an output to an input
The following table defines the timing parameters for changing the XFx pin from an output pin to an input pin.
timing requirements for changing XFx from output to input mode (see Figure 25)
MIN
MAX
UNIT
tsu(XF-H1L)
Setup time, XFx before H1 low
4
ns
th(H1L-XF)
Hold time, XFx after H1 low
0
ns
switching characteristics over recommended operating conditions for changing XFx from output to
input mode (see Figure 25)
PARAMETER
tdis(H3H-XF)
MIN
Disable time, XFx after H3 high
MAX
UNIT
5*
ns
* Not production tested
Buffers Go
From Output
to Output
Execute
Load of IOF
Synchronizer
Delay
Value on Pin
Seen in IOF
H3
H1
tsu(XF-H1L)
I/OxFx Bit
(see Note A)
th(H1L-XF)
tdis(H3H-XF)
XFx
Output
Data
Sampled
INXFx Bit
(see Note A)
Data
Seen
NOTE A: I/OxFx represents either bit 1 or bit 5 of the IOF register, and INXFx represents either bit 3 or bit 7 of the IOF register.
Figure 25. Timing for Changing XFx From Output to Input Mode
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
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changing XFx from an input to an output
The following table defines the timing parameter for changing the XFx pin from an input pin to an output pin.
switching characteristics over recommended operating conditions for changing XFx from input to
output mode (see Figure 26)
PARAMETER
td(H3H-XF)
MIN
Delay time, H3 high to XFx switching from input to output
MAX
UNIT
3
ns
Execution of
Load of IOF
H3
H1
I/OxFx Bit
(see Note A)
td(H3H-XF)
XFx
NOTE A: I/OxFx represents either bit 1 or bit 5 of the IOF register.
Figure 26. Timing for Changing XFx From Input to Output Mode
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
reset timing
RESET is an asynchronous input that can be asserted at any time during a clock cycle. If the specified timings
are met, the exact sequence shown in Figure 27 occurs; otherwise, an additional delay of one clock cycle is
possible.
The asynchronous reset signals include XF0/1, CLKX0, DX0, FSX0, CLKR0, DR0, FSR0, and TCLK0/1.
Resetting the device initializes the bus control register to seven software wait states and therefore results in slow
external accesses until these registers are initialized.
HOLD is a synchronous input that can be asserted during reset. It can take nine CPU cycles before HOLDA
is granted.
The following table defines the timing parameters for the RESET signal. The numbers shown in Figure 27
correspond with those in the NO. column of the following table.
timing requirements for RESET (see Figure 27)
MIN
tsu(RESET-EXTCLKL)
Setup time, RESET before EXTCLK low
5*
tsu(RESETH-H1L)
Setup time, RESET high before H1 low and after ten H1 clock cycles
5
MAX
P - 7*†
UNIT
ns
ns
* Not production tested
†P=t
c(EXTCLK)
switching characteristics over recommended operating conditions for RESET (see Figure 27)
PARAMETER
MIN*
MAX*
UNIT
td(EXTCLKH-H1H)
Delay time, EXTCLK high to H1 high
2
7
ns
td(EXTCLKH-H1L)
Delay time, EXTCLK high to H1 low
2
7
ns
td(EXTCLKH-H3L)
Delay time, EXTCLK high to H3 low
2
7
ns
td(EXTCLKH-H3H)
Delay time, EXTCLK high to H3 high
2
7
ns
tdis(H1H-DZ)
Disable time, Data (high impedance) from H1 high‡
6
ns
tdis(H3H-AZ)
Disable time, Address (high impedance) from H3 high
6
ns
td(H3H-CONTROLH)
Delay time, H3 high to control signals high
3
ns
td(H1H-RWH)
Delay time, H1 high to R/W high
3
ns
td(H1H-IACKH)
Delay time, H1 high to IACK high
3
ns
tdis(RESETL-ASYNCH)
Disable time, Asynchronous reset signals disabled (high impedance) from RESET
low§
6
ns
* Not production tested
‡ High impedance for Dbus is limited to nominal bus keeper Z
OUT = 15 kΩ.
§ Asynchronous reset signals include XF0/1, CLKX0, DX0, FSX0, CLKR0, DR0, FSR0, and TCLK0/1.
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
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reset timing (continued)
EXTCLK
tsu(RESET-EXTCLKL)
RESET
(see Notes A and C)
td(EXTCLKH-H1H)
t
tsu(RESETH-H1L)
d(EXTCLKH-H1L)
H1
td(EXTCLKH-H3L)
H3
Ten H1 Clock Cycles
tdis(H1H-DZ)
D[31:0]
td(EXTCLKH-H3H)
tdis(H3H-AZ)
PAGEx, A[23:0]
td(H3H-CONTROLH)
STRB
td(H1H-RWH)
R/W
td(H1H-IACKH)
IACK
Asynchronous
Reset Signals
(see Note B)
tdis(RESETL-ASYNCH)
NOTES: A. Clock circuit is configured in C31-compatible divide-by-2 mode. If configured for x1 mode, EXTCLK directly drives H3.
B. Asynchronous reset signals include XF0/1, CLKX0, DX0, FSX0, CLKR0, DR0, FSR0, and TCLK0/1.
C. RESET is a synchronous input that can be asserted at any point during a clock cycle. If the specified timings are met, the exact
sequence shown occurs; otherwise, an additional delay of one clock cycle is possible.
D. In microprocessor mode, the reset vector is fetched twice, with seven software wait states each time. In microcomputer mode, the
reset vector is fetched twice, with no software wait states.
E. The address and PAGE3-PAGE0 outputs are placed in a high-impedance state during reset requiring a nominal 10-22 kΩ pullup.
If not, undesirable spurious reads can occur when these outputs are not driven.
Figure 27. RESET Timing
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
interrupt response timing
The following table defines the timing parameters for the INTx signals.
timing requirements for INT3-INT0 response (see Figure 28)
MIN
tsu(INT-H1L)
Setup time, INT3- INT0 before H1 low
th(H1L-INT)
Hold time, INT3- INT0 after H1 low
tw(INT)
NOM
MAX
4*
ns
0
Pulse duration, interrupt to ensure only one interrupt
P+
5*†
UNIT
1.5P
2P -
ns
5*†
ns
* Not production tested
†P=t
c(H)
The interrupt (INTx) pins are synchronized inputs that can be asserted at any time during a clock cycle. The
TMS320C3x interrupts are selectable as level- or edge-sensitive. Interrupts are detected on the falling edge of
H1. Therefore, interrupts must be set up and held to the falling edge of the internal H1 for proper detection. The
CPU and DMA respond to detected interrupts on instruction-fetch boundaries only.
For the processor to recognize only one interrupt when level mode is selected, an interrupt pulse must be set
up and held such that a logic-low condition occurs for:
D A minimum of one H1 falling edge
D No more than two H1 falling edges
D Interrupt sources whose edges cannot be specified to meet the H1 falling edge setup and hold times must
be further restriced in pulse width as defined by tw(INT) (parameter 51) in the table above.
When EDGEMODE=1, the falling edge of the INT0-INT3 pins are detected using synchronous logic (see
Figure 7). The pulse low and high time should be two CPU clocks or greater.
The TMS320C3x can set the interrupt flag from the same source as quickly as two H1 clock cycles after it has
been cleared.
If the specified timings are met, the exact sequence shown in Figure 28 occurs; otherwise, an additional delay
of one clock cycle is possible.
40
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
interrupt response timing (continued)
Reset or
Interrupt
Vector Read
Fetch First
Instruction of
Service
Routine
H3
H1
tsu(INT-H1L)‡
th(H1L-INT)
tsu(INT-H1L)†
tsu(INT-H1L)¶
INT3 - INT0 Pin
(EDGEMODE = 0)
tw(INT)§
INT3 - INT0 Pin
(EDGEMODE = 1)
INT3 - INT0
Flag
ADDR
Vector Address
First Instruction Address
Data
†
Falling edge of H1 just detects INTx falling edge.
Falling edge of H1 detects second INTx low, however flag clear takes precedence.
§ Nominal width.
¶ Falling edge of H1 misses previous INTx low as INTx rises.
‡
Figure 28. INT3-INT0 Response Timing
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
interrupt-acknowledge timing
The IACK output goes active on the first half-cycle (HI rising) of the decode phase of the IACK instruction and
goes inactive at the first half-cycle (HI rising) of the read phase of the IACK instruction.
The following table defines the timing parameters for the IACK signal. The numbers shown in Figure 29
correspond with those in the NO. column of the table below.
NOTE: The IACK instruction can be executed at anytime to signal an event. It is most often used within an
interrupt routine to signal which interrupt has occurred.
switching characteristics over recommended operating conditions for IACK (see Figure 29)
MAX
UNIT
td(H1H-IACKL)
Delay time, H1 high to IACK low
PARAMETER
-1*
MIN
3
ns
td(H1H-IACKH)
Delay time, H1 high to IACK high
-1*
3
ns
* Not production tested
Fetch IACK
Instruction
Decode IACK
Instruction
IACK Data
Read
H3
H1
td(H1H-IACKL)
td(H1H-IACKH)
IACK
ADDR
Data
Figure 29. Interrupt Acknowledge (IACK) Timing
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
serial-port timing parameters
The following tables define the timing parameters for the serial port.
timing requirements (see Figure 30 and Figure 31)
MIN
tc(SCK)
Cycle time,
time CLKX/R
tw(SCK)
Pulse duration,
duration CLKX/R high/low
tr(SCK)
Rise time, CLKX/R
tf(SCK)
Fall time, CLKX/R
tsu(DR-CLKRL)
Setup time,
time DR before CLKR low
th(CLKRL-DR)
Hold time,
time DR after CLKR low
tsu(FSR-CLKRL)
Setup time,
time FSR before CLKR low
th(SCKL-FS)
Hold time,
time FSX/R input after CLKX/R low
tsu(FSX-CLKX)
Setup time,
time external FSX before CLKX
CLKX/R ext
tc(H) x 2.6*
CLKX/R int
tc(H) x 4*†
CLKX/R ext
tc(H) + 5
CLKX/R int
[tc(SCK)/2] - 4*
CLKR ext
4*
CLKR int
5*
CLKR ext
3*
CLKR int
0*
CLKR ext
4*
CLKR int
5*
CLKX/R ext
3*
CLKX/R int
0*
MAX
tc(H) x 216*
[tc(SCK)/2] + 4*
UNIT
ns
ns
3*
ns
3*
ns
ns
ns
ns
ns
CLKX ext
-[t c(H) - 6]
[tc(SCK)/2] - 6*
CLKX int
-[t c(H) - 10]*
tc(SCK)/2*
ns
* Not production tested
† A cycle time of t
c(H)*2 is possible when the device is operated at lower CPU frequencies. See the TMS320VC33 Silicon Update (literature number
SPRZ176) for further details.
switching characteristics over recommended operating conditions (see Figure 30 and Figure 31)
PARAMETER
td(H1H-SCK)
MIN
Delay time, H1 high to internal CLKX/R
MAX
UNIT
4*
ns
CLKX ext
6
CLKX int
5*
CLKX ext
5
td(CLKX-DX)
Delay time,
time CLKX to DX valid
ns
td(CLKX-FSX)
Delay time,
time CLKX to internal FSX high/low
CLKX int
4*
td(CLKX-DX)V
Delay time, CLKX to first DX bit, FSX precedes CLKX CLKX ext
high
CLKX int
5*
td(FSX-DX)V
Delay time, FSX to first DX bit, CLKX precedes FSX
6
ns
tdis(CLKX-DXZ)
Disable time, DX high impedance following last data bit from CLKX high
6
ns
ns
4
ns
* Not production tested
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
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data-rate timing modes
Unless otherwise indicated, the data-rate timings shown in Figure 30 and Figure 31 are valid for all serial-port
modes, including handshake. For a functional description of serial-port operation, see the TMS320C3x User’s
Guide (literature number SPRU031).
The serial-port timing parameters are defined in the preceding “serial-port timing parameters” tables. The
numbers shown in Figure 30 and Figure 31 correspond with those in the NO. column of each table.
tc(SCK)
td(H1H-SCK)
H1
td(H1H-SCK)
tw(SCK)
tw(SCK)
CLKX/R
tf(SCK)
td(CLKX- DX)
td(CLKX- DX)V
th(CLKRL- DR)
Bit n-1
DX
tr(SCK)
tdis(CLKX- DXZ)
Bit n-2
Bit 0
tsu(DR- CLKRL)
DR
Bit n-1
Bit n-2
FSR
tsu(FSR- CLKRL)
td(CLKX- FSX)
td(CLKX- FSX)
FSX(INT)
th(SCKL- FS)
FSX(EXT)
th(SCKL- FS)
tsu(FSX- CLKX)
NOTES: A. Timing diagrams show operations with CLKXP = CLKRP = FSXP = FSRP = 0.
B. Timing diagrams depend on the length of the serial-port word, where n = 8, 16, 24, or 32 bits, respectively.
Figure 30. Fixed Data-Rate Mode Timing
CLKX/R
td(CLKX- FSX)
FSX(INT)
tsu(FSX- CLKX)
td(FSX- DX)V
FSX(EXT)
td(CLKX- DX)
td(CLKX-DX)V
DX
Bit n-1
th(SCKL-FS)
tdis(CLKX-DXZ)
Bit n-2
Bit n-3
Bit 0
FSR
tsu(FSR-CLKRL)
DR
tsu(DR- CLKRL)
Bit n-1
Bit n-2
Bit n-3
th(CLKRL-DR)
NOTES: A. Timing diagrams show operation with CLKXP = CLKRP = FSXP = FSRP = 0.
B. Timing diagrams depend on the length of the serial-port word, where n = 8, 16, 24, or 32 bits, respectively.
C. The timings that are not specified expressly for the variable data-rate mode are the same as those that are specified for the fixed
data-rate mode.
Figure 31. Variable Data-Rate Mode Timing
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DIGITAL SIGNAL PROCESSOR
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HOLD timing
HOLD is a synchronous input that can be asserted at any time during a clock cycle. If the specified timings are
met, the exact sequence shown in Figure 32 and Figure 33 occurs; otherwise, an additional delay of one clock
cycle is possible.
The table, “timing parameters for HOLD/HOLDA”, defines the timing parameters for the HOLD and HOLDA
signals. The numbers shown in Figure 32 and Figure 33 correspond with those in the NO. column of the table.
The NOHOLD bit of the primary-bus control register overrides the HOLD signal. When this bit is set, the device
comes out of hold and prevents future hold cycles.
Asserting HOLD prevents the processor from accessing the primary bus. Program execution continues until a
read from or a write to the primary bus is requested. In certain circumstances, the first write is pending, thus
allowing the processor to continue (internally) until a second external write is encountered.
Figure 32, Figure 33, and the accompaning timings are for a zero wait-state bus configuration. Since HOLD is
internally captured by the CPU on the H1 falling edge one cycle before the present cycle is terminated, the
minimum HOLD width for any bus configuration is, therefore, WTCNT+3. Also, HOLD should not be deasserted
before HOLDA has been active for at least one cycle.
timing requirements for HOLD/HOLDA (see Figure 32 and Figure 33)
MIN
tsu(HOLD-H1L)
Setup time, HOLD before H1 low
tw(HOLD)
Pulse duration, HOLD low
MAX
UNIT
3
ns
3tc(H)*
ns
*Not production tested.
switching characteristics over
(see Figure 32 and Figure 33)
recommended
operating
conditions
for
PARAMETER
MIN
tv(H1L-HOLDA)
Valid time, HOLDA after H1 low
-1*
tw(HOLDA)
Pulse duration, HOLDA low
td(H1L-SH)H
Delay time, H1 low to STRB high for a HOLD
tdis(H1L-S)
Disable time, STRB to the high-impedance state from H1 low
ten(H1L-S)
tdis(H1L-RW)
HOLD/HOLDA
MAX
3*
2tc(H) - 4*
-1
UNIT
ns
ns
3
ns
4
ns
Enable time, STRB enabled (active) from H1 low
4
ns
Disable time, R/W to the high-impedance state from H1 low
5*
ns
ten(H1L-RW)
Enable time, R/W enabled (active) from H1 low
4
ns
tdis(H1L-A)
Disable time, Address to the high-impedance state from H1 low
4*
ns
ten(H1L-A)
Enable time, Address enabled (valid) from H1 low
5
ns
tdis(H1H-D)
Disable time, Data to the high-impedance state from H1 high
4*
ns
* Not production tested
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
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HOLD timing (continued)
H3
H1
tsu(HOLD- H1L)
HOLD
tsu(HOLD- H1L)
tw(HOLD)
tv(H1L-HOLDA)
HOLDA
tw(HOLDA)
tv(H1L- HOLDA)
td(H1L-SH)H
ten(H1L-S)
tdis(H1L-S)
STRB, PAGEx
ten(H1L-RW)
tdis(H1L-RW)
R/W
ten(H1L-A)
tdis(H1L-A)
A[23:0]
tdis(H1H-D)
D[31:0]
Write Data
NOTE A: HOLDA goes low in response to HOLD going low and continues to remain low until one H1 cycle
after HOLD goes back high.
Figure 32. Timing for HOLD/HOLDA (After Write)
H3
H1
tsu(HOLD- H1L)
HOLD
tsu(HOLD- H1L)
tw(HOLD)
tv(H1L- HOLDA)
tw(HOLDA)
HOLDA
tv(H1L- HOLDA)
td(H1L-SH)H
tdis(H1L-S)
ten(H1L-S)
STRB, PAGEx
tdis(H1L-RW)
ten(H1L-RW)
R/W
tdis(H1L-A)
ten(H1L-A)
A[23:0]
D[31:0]
Read Data
NOTE A: HOLDA goes low in response to HOLD going low and continues to remain low until one H1 cycle
after HOLD goes back high.
Figure 33. Timing for HOLD/HOLDA (After Read)
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DIGITAL SIGNAL PROCESSOR
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general-purpose I/O timing
Peripheral pins include CLKX0, CLKR0, DX0, DR0, FSX0, FSR0, and TCLK0/1. The contents of the internal
control registers associated with each peripheral define the modes for these pins.
peripheral pin I/O timing
The following table shows the timing parameters for changing the peripheral pin from a general-purpose output
pin to a general-purpose input pin and vice versa.
timing requirements for peripheral pin general-purpose I/O (see Note 1, Figure 34, and Figure 35)
MIN
MAX
UNIT
tsu(GPIO-H1L)
Setup time, general-purpose input before H1 low
3*
ns
th(H1L-GPIO)
Hold time, general-purpose input after H1 low
0*
ns
* Not production tested
NOTE 1: Peripheral pins include CLKX0, CLKR0, DX0, DR0, FSX0, FSR0, and TCLK0/1. The modes of these pins are defined by the contents
of internal-control registers associated with each peripheral.
switching characteristics over recommended operating conditions for peripheral pin
general-purpose I/O (see Note 1, Figure 34, and Figure 35)
PARAMETER
MIN
MAX
UNIT
td(H1H-GPIO)
Delay time, H1 high to general-purpose output
4
ns
tdis(H1H)
Disable time, general-purpose output from H1 high
5
ns
NOTE 1: Peripheral pins include CLKX0, CLKR0, DX0, DR0, FSX0, FSR0, and TCLK0/1. The modes of these pins are defined by the contents
of internal-control registers associated with each peripheral.
Execution
of Store of
PeripheralControl
Register
Buffers Go
From
Output to
Input
Synchronizer Delay
Value on Pin
Seen in
PeripheralControl
Register
H3
H1
tsu(GPIO-H1L)
I/O
Control Bit
Peripheral Pin
(see Note A)
Data Bit
th(H1L-GPIO)
tdis(H1H)
Output
Data
Sampled
Data
Seen
NOTE A: Peripheral pins include CLKX0, CLKR0, DX0, DR0, FSX0, FSR0, and TCLK0/1.
Figure 34. Change of Peripheral Pin From General-Purpose Output to Input Mode Timing
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47
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
peripheral pin I/O timing (continued)
Execution of Store
of PeripheralControl Register
H3
H1
I/O
Control
Bit
td(H1H-GPIO)
td(H1H-GPIO)
Peripheral Pin
(see Note A)
NOTE A: Peripheral pins include CLKX0, CLKR0, DX0, DR0, FSX0, FSR0, and TCLK0/1.
Figure 35. Change of Peripheral Pin From General-Purpose Input to Output Mode Timing
48
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
timer pin timing
Valid logic-level periods and polarity are specified by the contents of the internal control registers. The following
tables define the timing parameters for the timer pin.
timing requirements for timer pin (see Figure 36 and Figure 37)
MIN
tsu(TCLK-H1L)†
th(H1L-TCLK)
†
MAX
UNIT
Setup time, TCLK external before H1 low
3*
ns
Hold time, TCLK external after H1 low
0
ns
* Not production tested
† These requirements are applicable for a synchronous input clock.
switching characteristics over recommended operating conditions for timer pin (see Figure 36 and
Figure 37)
MIN
PARAMETER
td(H1H-TCLK)
Delay time, H1 high to TCLK internal valid
tc(TCLK)‡
Cycle time,
time TCLK
tw(TCLK)‡
Pulse duration,
duration TCLK
MAX
3
TCLK ext
tc(H) x 2.6*
TCLK int
tc(H) x 2*
TCLK ext
tc(H) + 5*
TCLK int
[tc(TCLK)/2] - 4*
tc(H) x 232*
[tc(TCLK)/2] + 4*
UNIT
ns
ns
ns
* Not production tested
‡ These parameters are applicable for an asynchronous input clock.
H3
H1
th(H1L-TCLK)
tsu(TCLK-H1L)
th(H1L-TCLK)
tsu(TCLK-H1L)
TCLK as input
tc(TCLK)
tw(TCLK)
Figure 36. Timer Pin Timing, Input
H3
H1
td(H1H-TCLK)
td(H1H-TCLK)
TCLK as output
Figure 37. Timer Pin Timing, Output
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49
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
SHZ pin timing
The following table defines the timing parameter for the SHZ pin.
switching characteristics over recommended operating conditions for SHZ (see Figure 38)
PARAMETER
tdis(SHZ)
Disable time, SHZ low to all outputs, I/O pins disabled (high impedance)
MIN
MAX
0*
8*
UNIT
ns
* Not production tested
SHZ
tdis(SHZ)
All I/O Pins
NOTE A: Enabling SHZ destroys SM/SMJ320VC33 register and memory contents.
Assert SHZ = 1 and reset the SM/SMJ320VC33 to restore it to a known
condition.
Figure 38. Timing for SHZ
test access port timing
The following table defines the timing parameter for the test access port.
timing for test access port (see Figure 39)
MIN
tsu(TMS-TCKH)
Setup time, TMS/TDI to TCK high
5*
th(TCKH-TMS)
Hold time, TMS/TDI from TCK high
5*
td(TCKL-TDOV)
Delay time, TCK low to TDO valid
0*
tr (TCK)
tf (TCK)
UNIT
ns
ns
10*
ns
Rise time, TCK
3*
ns
Fall time, TCK
3*
ns
* Not production tested
TCK
tr(TCK)
tf(TCK)
tsu(TMS-TCKH)
TMS/TDI
td(TCHL-TDOV)
th(TCHK-TMS)
TDO
Figure 39. IEEE-1149.1 Test Access Port Timings
50
MAX
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SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
MECHANICAL DATA
GNM (S-CBGA-N144)
CERAMIC BALL GRID ARRAY
12,15
SQ
11,85
9,60 TYP
0,80
0,80
N
M
L
K
J
H
G
F
E
D
C
B
A
1 2 3 4 5 6 7 8 9 10 11 12 13
2,40 MAX
0,56
0,34
Seating Plane
0,55
0,45
∅ 0,10 M
0,50
0,35
0,12
4201017/B 05/01
NOTES: A. All linear dimensions are in millimeters.
B. This drawing is subject to change without notice.
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51
SM320VC33, SMJ320VC33
DIGITAL SIGNAL PROCESSOR
SGUS034E - FEBRUARY 2001 - REVISED OCTOBER 2002
MECHANICAL DATA
HFG (S-CQFP-F164)
CERAMIC QUAD FLATPACK WITH NCTB
1.140 (28,96)
SQ
1.120 (28,45)
0.325 (8,26)
Tie Bar Width
0.275 (6,99)
1.000 (25,40)
BSC
”A”
41
1
42
164
Á
Á
Á
Á
1.520 (38,61)
1.480 (37,59)
2.505 (63,63)
2.485 (63,12)
82
124
83
1.150 (29,21)
BSC 8 Places
0.061 (1,55)
DIA 4 Places
0.059 (1,50)
123
Á
Á
Á
Á
”C”
”B”
0.105 (2,67) MAX
0.018 (0,46) MAX
164 X
0.010 (0,25)
0.006 (0,15)
BRAZE
0.040 (1,02)
0.030 (0,76)
0,025 (0,64)
DETAIL ”A”
0.009 (0,23)
0.004 (0,10)
0.020 (0,51) MAX
DETAIL ”B”
0.014 (0,36)
0.002 (0,05)
0.130 (3,30) MAX
DETAIL ”C”
4040231-9/J 01/99
NOTES: C.
D.
E.
F.
G.
H.
I.
52
All linear dimensions are in inches (millimeters).
This drawing is subject to change without notice.
Ceramic quad flatpack with flat leads brazed to non-conductive tie bar carrier
This package is hermetically sealed with a metal lid.
The leads are gold-plated and can be solder-dipped.
Leads not shown for clarity purposes
Falls within JEDEC MO-113AA (REV D)
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PACKAGE OPTION ADDENDUM
www.ti.com
25-Feb-2005
PACKAGING INFORMATION
Orderable Device
Status (1)
Package
Type
Package
Drawing
Pins Package Eco Plan (2)
Qty
Lead/Ball Finish
MSL Peak Temp (3)
5962-0053901QYA
ACTIVE
CFP
HFG
164
1
None
Call TI
Level-NC-NC-NC
5962-0053901QYC
ACTIVE
CFP
HFG
164
1
None
Call TI
Level-NC-NC-NC
5962-0053902QYA
ACTIVE
CFP
HFG
164
1
None
Call TI
Level-NC-NC-NC
5962-0053902QYC
ACTIVE
CFP
HFG
164
4
None
Call TI
Level-NC-NC-NC
SM320VC33GNMM150
ACTIVE
CBGA
GNM
144
1
None
Call TI
Level-1-235C-UNLIM
SMJ320VC33HFGM150
ACTIVE
CFP
HFG
164
1
None
Call TI
Level-NC-NC-NC
(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 - May not be currently available - please check http://www.ti.com/productcontent for the latest availability information and additional
product content details.
None: Not yet available Lead (Pb-Free).
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" and in addition, uses package materials that do not contain halogens,
including bromine (Br) or antimony (Sb) above 0.1% of total product weight.
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDECindustry 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
accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and continues to take
reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on
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.
Addendum-Page 1
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