TI SM320C6701GLPS16

SGUS030B – APRIL 2000 – REVISED MAY 2001
D Highest Performance Floating-Point Digital
D
D
D
D
D
Signal Processor (DSP) SMJ320C6701
– 7-, 6-ns Instruction Cycle Time
– 140-, 167-MHz Clock Rate
– Eight 32-Bit Instructions/Cycle
– Up to 1 GFLOPS Performance
– Pin-Compatible With ’C6201 Fixed-Point
DSP
SMJ: QML Processing to MIL-PRF-38535
SM: Standard Processing
Operating Temperature Ranges
– Extended (W) –55°C to 115°C
– Extended (S) –40°C to 90°C
VelociTI Advanced Very Long Instruction
Word (VLIW) ’C67x CPU Core
– Eight Highly Independent Functional
Units:
– Four ALUs (Floating- and Fixed-Point)
– Two ALUs (Fixed-Point)
– Two Multipliers (Floating- and
Fixed-Point)
– Load-Store Architecture With 32 32-Bit
General-Purpose Registers
– Instruction Packing Reduces Code Size
– All Instructions Conditional
Instruction Set Features
– Hardware Support for IEEE
Single-Precision Instructions
– Hardware Support for IEEE
Double-Precision Instructions
– Byte-Addressable (8-, 16-, 32-Bit Data)
– 32-Bit Address Range
– 8-Bit Overflow Protection
– Saturation
– Bit-Field Extract, Set, Clear
– Bit-Counting
– Normalization
D 1M-Bit On-Chip SRAM
D
D
D
D
D
D
D
D
D
D
– 512K-Bit Internal Program/Cache
(16K 32-Bit Instructions)
– 512K-Bit Dual-Access Internal Data
(64K Bytes)
32-Bit External Memory Interface (EMIF)
– Glueless Interface to Synchronous
Memories: SDRAM and SBSRAM
– Glueless Interface to Asynchronous
Memories: SRAM and EPROM
Four-Channel Bootloading
Direct-Memory-Access (DMA) Controller
With an Auxiliary Channel
16-Bit Host-Port Interface (HPI)
– Access to Entire Memory Map
Two Multichannel Buffered Serial Ports
(McBSPs)
– Direct Interface to T1/E1, MVIP, SCSA
Framers
– ST-Bus-Switching Compatible
– Up to 256 Channels Each
– AC97-Compatible
– Serial-Peripheral-Interface (SPI)
Compatible (Motorola)
Two 32-Bit General-Purpose Timers
Flexible Phase-Locked-Loop (PLL) Clock
Generator
IEEE-1149.1 (JTAG†)
Boundary-Scan-Compatible
429-Pin Ceramic Ball Grid Array (CBGA)
Package (GLP Suffix)
0.18-µm/5-Level Metal Process
– CMOS Technology
3.3-V I/Os, 1.9-V Internal
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.
VelociTI is a trademark of Texas Instruments Incorporated.
Motorola is a trademark of Motorola, Inc.
† IEEE Standard 1149.1-1990 Standard-Test-Access Port and Boundary Scan Architecture.
Copyright  2001, Texas Instruments Incorporated
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description
The SMJ320C67x DSPs are the floating-point DSP family in the SMJ320C6000 platform. The SMJ320C6701
(’C6701) device is based on the high-performance, advanced VelociTI very-long-instruction-word (VLIW)
architecture developed by Texas Instruments (TI), making this DSP an excellent choice for multichannel and
multifunction applications. With performance of up to 1 giga floating-point operations per second (GFLOPS) at
a clock rate of 167 MHz, the ’C6701 offers cost-effective solutions to high-performance DSP programming
challenges. The ’C6701 DSP possesses the operational flexibility of high-speed controllers and the numerical
capability of array processors. This processor has 32 general-purpose registers of 32-bit word length and eight
highly independent functional units. The eight functional units provide four floating-/fixed-point ALUs, two
fixed-point ALUs, and two floating-/fixed-point multipliers. The ’C6701 can produce two multiply-accumulates
(MACs) per cycle for a total of 334 million MACs per second (MMACS). The ’C6701 DSP also has
application-specific hardware logic, on-chip memory, and additional on-chip peripherals.
The ’C6701 includes a large bank of on-chip memory and has a powerful and diverse set of peripherals.
Program memory consists of a 64K-byte block that is user-configurable as cache or memory-mapped program
space. Data memory consists of two 32K-byte blocks of RAM. The peripheral set includes two multichannel
buffered serial ports (McBSPs), two general-purpose timers, a host-port interface (HPI), and a glueless external
memory interface (EMIF) capable of interfacing to SDRAM or SBSRAM and asynchronous peripherals.
The ’C6701 has a complete set of development tools which includes: a new C compiler, an assembly optimizer
to simplify programming and scheduling, and a Windows debugger interface for visibility into source code
execution.
TI is a trademark of Texas Instruments Incorporated.
Windows is a registered trademark of the Microsoft Corporation.
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device characteristics
Table 1 provides an overview of the ’C6701 DSP. The table shows significant features of each device, including
the capacity of on-chip RAM, the peripherals, the execution time, and the package type with pin count.
Table 1. Characteristics of the ’C6701 Processors
CHARACTERISTICS
DESCRIPTION
Device Number
SMJ320C6701
On-Chip Memory
512-Kbit Program Memory
512-Kbit Data Memory (organized as 2 blocks)
Peripherals
2 Mutichannel Buffered Serial Ports (McBSP)
2 General-Purpose Timers
Host-Port Interface (HPI)
External Memory Interface (EMIF)
Cycle Time
7 ns at 140 MHz, and 6 ns at 167 MHz
Package Type
27 mm × 27 mm, 429-Pin BGA (GLP)
Nominal Voltage
1.9 V Core
3.3 V I/O
functional and CPU block diagram
’C6701 Digital Signal Processor
Program
Bus
SDRAM
SBSRAM
32
SRAM
External Memory
Interface (EMIF)
ROM/FLASH
Internal Program Memory
1 Block Program/Cache
(64K Bytes)
Program
Access/Cache
Controller
I/O Devices
’C67x CPU
Instruction Fetch
Timer 1
Instruction Dispatch
16
Host Port
Interface
(HPI)
Data Bus
DMA Buses
Multichannel
Buffered Serial
Port 1
Control
Registers
Control
Logic
Instruction Decode
Multichannel
Buffered Serial
Port 0
Framing Chips:
H.100, MVIP,
SCSA, T1, E1
AC97 Devices,
SPI Devices,
Codecs
HOST CONNECTION
MC68360 Glueless
MPC860 Glueless
PCI9050 Bridge + Inverter
MC68302 + PAL
MPC750 + PAL
MPC960 (Jx/Rx) + PAL
Timer 0
Data Path B
B Register File
In-Circuit
Emulation
.D2 .M2† .S2† .L2†
Interrupt
Control
.L1† .S1† .M1† .D1
Direct Memory
Access Controller
(DMA)
(4 Channels)
PLL
(x1, x4)
Data Path A
A Register File
PowerDown
Logic
Data
Access
Controller
Test
Internal Data
Memory
(64K Bytes)
2 Blocks of 8 Banks
Each
† These functional units execute floating-point instructions.
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SGUS030B – APRIL 2000 – REVISED MAY 2001
CPU description
The CPU fetches VelociTI advanced very-long instruction words (VLIW) (256 bits wide) to supply up to eight
32-bit instructions to the eight functional units during every clock cycle. The VelociTI VLIW architecture features
controls by which all eight units do not have to be supplied with instructions if they are not ready to execute. The
first bit of every 32-bit instruction determines if the next instruction belongs to the same execute packet as the
previous instruction, or whether it should be executed in the following clock as a part of the next execute packet.
Fetch packets are always 256 bits wide; however, the execute packets can vary in size. The variable-length
execute packets are a key memory-saving feature, distinguishing the ’C67x CPU from other VLIW architectures.
The CPU features two sets of functional units. Each set contains four units and a register file. One set contains
functional units .L1, .S1, .M1, and .D1; the other set contains units .D2, .M2, .S2, and .L2. The two register files
contain 16 32-bit registers each for the total of 32 general-purpose registers. The two sets of functional units,
along with two register files, compose sides A and B of the CPU (see the functional and CPU block diagram
and Figure 1). The four functional units on each side of the CPU can freely share the 16 registers belonging to
that side. Additionally, each side features a single data bus connected to all registers on the other side, by which
the two sets of functional units can access data from the register files on opposite sides. While register access
by functional units on the same side of the CPU as the register file can service all the units in a single clock cycle,
register access using the register file across the CPU supports one read and one write per cycle.
The ’C67x CPU executes all ’C62x instructions. In addition to ’C62x fixed-point instructions, the six out of eight
functional units (.L1, .M1, .D1, .D2, .M2, and .L2) also execute floating-point instructions. The remaining two
functional units (.S1 and .S2) also execute the new LDDW instruction which loads 64 bits per CPU side for a
total of 128 bits per cycle.
Another key feature of the ’C67x CPU is the load/store architecture, where all instructions operate on registers
(as opposed to data in memory). Two sets of data-addressing units (.D1 and .D2) are responsible for all data
transfers between the register files and the memory. The data address driven by the .D units allows data
addresses generated from one register file to be used to load or store data to or from the other register file. The
’C67x CPU supports a variety of indirect-addressing modes using either linear- or circular-addressing modes
with 5- or 15-bit offsets. All instructions are conditional, and most can access any one of the 32 registers. Some
registers, however, are singled out to support specific addressing or to hold the condition for conditional
instructions (if the condition is not automatically “true”). The two .M functional units are dedicated for multiplies.
The two .S and .L functional units perform a general set of arithmetic, logical, and branch functions with results
available every clock cycle.
The processing flow begins when a 256-bit-wide instruction fetch packet is fetched from a program memory.
The 32-bit instructions destined for the individual functional units are “linked” together by “1” bits in the least
significant bit (LSB) position of the instructions. The instructions that are “chained” together for simultaneous
execution (up to eight in total) compose an execute packet. A “0” in the LSB of an instruction breaks the chain,
effectively placing the instructions that follow it in the next execute packet. If an execute packet crosses the
fetch-packet boundary (256 bits wide), the assembler places it in the next fetch packet, while the remainder of
the current fetch packet is padded with NOP instructions. The number of execute packets within a fetch packet
can vary from one to eight. Execute packets are dispatched to their respective functional units at the rate of one
per clock cycle and the next 256-bit fetch packet is not fetched until all the execute packets from the current fetch
packet have been dispatched. After decoding, the instructions simultaneously drive all active functional units
for a maximum execution rate of eight instructions every clock cycle. While most results are stored in 32-bit
registers, they can be subsequently moved to memory as bytes or half-words as well. All load and store
instructions are byte-, half-word, or word-addressable.
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CPU description (continued)
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src1
.L1† src2
dst
long dst
long src
LD1 32 MSB
ST1
long src
long dst
dst
.S1†
src1
Data Path A
8
8
32
32
8
8
Á
Á
Á
Á
src2
dst
src1
†
.M1
src2
LD1 32 LSB
DA1
DA2
LD2 32 LSB
Á
Á
Á
Á
.D1
.D2
dst
src1
src2
src2
src2
.S2†
LD2 32 MSB
ST2
Á
Á
long src
long dst
dst
.L2†
src2
src1
Register
File A
(A0–A15)
1X
.M2† src1
dst
Data Path B
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2X
src2
src1
dst
src1
dst
long dst
long src
Á
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Á
8
Á
Á
Á
Á
Register
File B
(B0–B15)
8
32
32
8
Á
Á
Á
Á
8
† These functional units execute floating-point instructions.
Control
Register File
Figure 1. SMJ320C67x CPU Data Paths
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SGUS030B – APRIL 2000 – REVISED MAY 2001
signal groups description
CLKIN
CLKOUT2
CLKOUT1
CLKMODE1
CLKMODE0
Boot Mode
BOOTMODE4
BOOTMODE3
BOOTMODE2
BOOTMODE1
BOOTMODE0
Reset and
Interrupts
RESET
NMI
EXT_INT7
EXT_INT6
EXT_INT5
EXT_INT4
IACK
INUM3
INUM2
INUM1
INUM0
Little ENDIAN
Big ENDIAN
LENDIAN
CLOCK/PLL
PLLFREQ3
PLLFREQ2
PLLFREQ1
PLLV
PLLG
PLLF
TMS
TDO
TDI
TCK
TRST
EMU1
EMU0
IEEE Standard
1149.1
(JTAG)
Emulation
RSV9
RSV8
RSV7
RSV6
RSV5
RSV4
RSV3
RSV2
RSV1
RSV0
DMA Status
DMAC3
DMAC2
DMAC1
DMAC0
Power-Down
Status
PD
Reserved
Control/Status
HD[15:0]
HCNTL0
HCNTL1
16
Data
HPI
(Host-Port Interface)
Register Select
Control
HHWIL
HBE1
HBE0
Half-Word/Byte
Select
Figure 2. CPU and Peripheral Signals
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HAS
HR/W
HCS
HDS1
HDS2
HRDY
HINT
SGUS030B – APRIL 2000 – REVISED MAY 2001
signal groups description (continued)
32
ED[31:0]
Data
CE3
CE2
CE1
CE0
EA[21:2]
BE3
BE2
BE1
BE0
HOLD
HOLDA
Asynchronous
Memory
Control
ARE
AOE
AWE
ARDY
Memory Map
Space Select
20
Word Address
SBSRAM
Control
SSADS
SSOE
SSWE
SSCLK
SDRAM
Control
SDA10
SDRAS
SDCAS
SDWE
SDCLK
Byte Enables
HOLD/
HOLDA
EMIF
(External Memory Interface)
TOUT1
Timer 1
Timer 0
TOUT0
TINP0
TINP1
Timers
McBSP1
McBSP0
CLKX1
FSX1
DX1
Receive
Receive
CLKX0
FSX0
DX0
CLKR1
FSR1
DR1
Transmit
Transmit
CLKR0
FSR0
DR0
CLKS1
Clock
Clock
CLKS0
McBSPs
(Multichannel Buffered Serial Ports)
Figure 3. Peripheral Signals
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SGUS030B – APRIL 2000 – REVISED MAY 2001
Signal Descriptions
SIGNAL
NAME
NO.
TYPE†
DESCRIPTION
CLOCK/PLL
CLKIN
A14
I
Clock Input
CLKOUT1
Y6
O
Clock output at full device speed
CLKOUT2
V9
O
Clock output at half of device speed
CLKMODE1
B17
CLKMODE0
C17
PLLFREQ3
C13
PLLFREQ2
G11
PLLFREQ1
PLLV‡
F11
D12
PLLG‡
Clock mode select
I
•
Selects whether the output clock frequency = input clock freq x4 or x1
PLL frequency range (3, 2, and 1)
I
•
The target range for CLKOUT1 frequency is determined by the 3-bit value of the PLLFREQ pins.
PLL analog VCC connection for the low-pass filter
G10
A§
A§
PLLF
C12
A§
PLL low-pass filter connection to external components and a bypass capacitor
TMS
K19
I
TDO
R12
O/Z
TDI
R13
I
JTAG test port data in (features an internal pull-up)
TCK
M20
I
JTAG test port clock
TRST
N18
I
JTAG test port reset (features an internal pull-down)
EMU1
R20
I/O/Z
EMU0
T18
I/O/Z
RESET
J20
I
Device reset
NMI
K21
I
Nonmaskable interrupt
• Edge-driven (rising edge)
EXT_INT7
R16
I
External interrupts
interru ts
• Edge-driven
g
(rising
g edge)
g
O
Interrupt acknowledge for all active interrupts serviced by the CPU
O
Active interrupt identification number
• Valid during IACK for all active interrupts (not just external)
• Encoding order follows the interrupt
interru t service fetch packet
acket ordering
I
If high, selects little-endian byte/half-word addressing order within a word
If low, selects big-endian addressing
PLL analog GND connection for the low-pass filter
JTAG EMULATION
JTAG test port mode select (features an internal pull-up)
JTAG test port data out
Emulation pin 1, pull-up with a dedicated 20-kΩ resistor¶
Emulation pin 0, pull-up with a dedicated 20-kΩ resistor¶
RESET AND INTERRUPTS
EXT_INT6
P20
EXT_INT5
R15
EXT_INT4
R18
IACK
R11
INUM3
T19
INUM2
T20
INUM1
T14
INUM0
T16
LITTLE ENDIAN/BIG ENDIAN
LENDIAN
G20
POWER DOWN STATUS
PD
D19
O
Power-down mode 2 or 3 (active if high)
† I = Input, O = Output, Z = High Impedance, S = Supply Voltage, GND = Ground
‡ PLLV and PLLG signals are not part of external voltage supply or ground. See the CLOCK/PLL documentation for information on how to connect
those pins.
§ A = Analog Signal (PLL Filter)
¶ For emulation and normal operation, pull up EMU1 and EMU0 with a dedicated 20-kΩ resistor. For boundary scan, pull down EMU1 and EMU0
with a dedicated 20-kΩ resistor.
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Signal Descriptions (Continued)
SIGNAL
NAME
NO.
TYPE†
DESCRIPTION
HOST PORT INTERFACE (HPI)
HINT
H2
O/Z
HCNTL1
J6
I
Host control – selects between control, address or data registers
HCNTL0
H6
I
Host control – selects between control, address or data registers
HHWIL
E4
I
Host halfword select – first or second halfword (not necessarily high or low order)
HBE1
G6
I
Host byte select within word or half-word
HBE0
F6
I
Host byte select within word or half-word
HR/W
D4
I
Host read or write select
HD15
D11
HD14
B11
HD13
A11
HD12
G9
HD11
D10
HD10
A10
HD9
C10
HD8
B9
HD7
F9
HD6
C9
HD5
A9
HD4
B8
HD3
D9
HD2
D8
HD1
B7
HD0
C7
I/O/Z
Host interrupt (from DSP to host)
( sed for transfer of data,
data address and control)
Host port data (used
HAS
L6
I
Host address strobe
HCS
C5
I
Host chip select
HDS1
C4
I
Host data strobe 1
HDS2
K6
I
Host data strobe 2
HRDY
H3
O
Host ready (from DSP to host)
BOOTMODE4
B16
BOOTMODE3
G14
BOOT MODE
BOOTMODE2
F15
BOOTMODE1
C18
I
Boot mode
BOOTMODE0
D17
† I = Input, O = Output, Z = High Impedance, S = Supply Voltage, GND = Ground
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Signal Descriptions (Continued)
SIGNAL
NAME
NO.
TYPE†
DESCRIPTION
EMIF – CONTROL SIGNALS COMMON TO ALL TYPES OF MEMORY
CE3
Y5
O/Z
CE2
V3
O/Z
Memory space enables
CE1
T6
O/Z
•
Enabled by bits 24 and 25 of the word address
CE0
U2
O/Z
•
Only one asserted during any external data access
BE3
R8
O/Z
Byte enable control
BE2
T3
O/Z
•
Decoded from the two lowest bits of the internal address
BE1
T2
O/Z
•
Byte write enables for most types of memory
BE0
R2
O/Z
•
Can be directly connected to SDRAM read and write mask signal (SDQM)
EA21
L4
EA20
L3
EA19
J2
EMIF – ADDRESS
EA18
J1
EA17
K1
EA16
K2
EA15
L2
EA14
L1
EA13
M1
EA12
M2
EA11
M6
EA10
N4
EA9
N1
EA8
N2
EA7
N6
EA6
P4
EA5
P3
EA4
P2
EA3
P1
O/Z
E ternal address ((word
External
ord address)
EA2
P6
† I = Input, O = Output, Z = High Impedance, S = Supply Voltage, GND = Ground
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Signal Descriptions (Continued)
SIGNAL
NAME
NO.
TYPE†
DESCRIPTION
EMIF – DATA
ED31
U18
ED30
U20
ED29
T15
ED28
V18
ED27
V17
ED26
V16
ED25
T12
ED24
W17
ED23
T13
ED22
Y17
ED21
T11
ED20
Y16
ED19
W15
ED18
V14
ED17
Y15
ED16
R9
ED15
Y14
ED14
V13
ED13
AA13
ED12
T10
ED11
Y13
ED10
W12
ED9
Y12
ED8
Y11
ED7
V10
ED6
AA10
ED5
Y10
ED4
W10
ED3
Y9
ED2
AA9
ED1
Y8
ED0
W9
I/O/Z
E ternal data
External
EMIF – ASYNCHRONOUS MEMORY CONTROL
ARE
R7
O/Z
Asynchronous memory read enable
AOE
T7
O/Z
Asynchronous memory output enable
AWE
V5
O/Z
Asynchronous memory write enable
ARDY
R4
I
Asynchronous memory ready input
† I = Input, O = Output, Z = High Impedance, S = Supply Voltage, GND = Ground
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Signal Descriptions (Continued)
SIGNAL
NAME
NO.
TYPE†
DESCRIPTION
EMIF – SYNCHRONOUS BURST SRAM CONTROL
SSADS
V8
O/Z
SBSRAM address strobe
SSOE
W7
O/Z
SBSRAM output enable
SSWE
Y7
O/Z
SBSRAM write enable
SSCLK
AA8
O/Z
SBSRAM clock
EMIF – SYNCHRONOUS DRAM CONTROL
SDA10
V7
O/Z
SDRAM address 10 (separate for deactivate command)
SDRAS
V6
O/Z
SDRAM row address strobe
SDCAS
W5
O/Z
SDRAM column address strobe
SDWE
T8
O/Z
SDRAM write enable
SDCLK
T9
O/Z
SDRAM clock
EMIF – BUS ARBITRATION
HOLD
R6
I
Hold request from the host
HOLDA
B15
O
Hold request acknowledge to the host
TOUT1
G2
O/Z
TINP1
K3
I
TOUT0
M18
O/Z
TINP0
J18
I
DMAC3
E18
DMAC2
F19
DMAC1
E20
DMAC0
G16
TIMERS
Timer 1 or general-purpose output
Timer 1 or general-purpose input
Timer 0 or general-purpose output
Timer 0 or general-purpose input
DMA ACTION COMPLETE
O
DMA action complete
MULTICHANNEL BUFFERED SERIAL PORT 1 (McBSP1)
CLKS1
F4
I
CLKR1
H4
I/O/Z
External clock source (as opposed to internal)
Receive clock
CLKX1
J4
I/O/Z
Transmit clock
DR1
E2
I
Receive data
DX1
G4
O/Z
Transmit data
FSR1
F3
I/O/Z
Receive frame sync
FSX1
F2
I/O/Z
Transmit frame sync
† I = Input, O = Output, Z = High Impedance, S = Supply Voltage, GND = Ground
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Signal Descriptions (Continued)
SIGNAL
NAME
NO.
TYPE†
DESCRIPTION
MULTICHANNEL BUFFERED SERIAL PORT 0 (McBSP0)
CLKS0
K18
I
CLKR0
L21
I/O/Z
External clock source (as opposed to internal)
Receive clock
CLKX0
K20
I/O/Z
Transmit clock
DR0
J21
I
Receive data
DX0
M21
O/Z
Transmit data
FSR0
P16
I/O/Z
Receive frame sync
FSX0
N16
I/O/Z
Transmit frame sync
RESERVED FOR TEST
RSV0
N21
I
Reserved for testing, pull-up with a dedicated 20-kΩ resistor
RSV1
K16
I
Reserved for testing, pull-up with a dedicated 20-kΩ resistor
RSV2
B13
I
Reserved for testing, pull-up with a dedicated 20-kΩ resistor
RSV3
B14
I
Reserved for testing, pull-up with a dedicated 20-kΩ resistor
RSV4
F13
I
Reserved for testing, pull-down with a dedicated 20-kΩ resistor
RSV5
C15
O
Reserved (leave unconnected, do not connect to power or ground)
RSV6
F7
I
Reserved for testing, pull-up with a dedicated 20-kW resistor
RSV7
D7
I
Reserved for testing, pull-up with a dedicated 20-kW resistor
RSV8
B5
I
Reserved for testing, pull-up with a dedicated 20-kW resistor
RSV9
F16
O
Reserved (leave unconnected, do not connect to power or ground)
SUPPLY VOLTAGE PINS
C14
C8
E19
E3
H11
H13
H9
J10
J12
J14
DVDD
J19
S
3.3-V
3.3
V supply
su ly voltage
J3
J8
K11
K13
K15
K7
K9
L10
L12
L14
† I = Input, O = Output, Z = High Impedance, S = Supply Voltage, GND = Ground
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Signal Descriptions (Continued)
SIGNAL
NAME
NO.
TYPE†
DESCRIPTION
SUPPLY VOLTAGE PINS (CONTINUED)
L8
M11
M13
M15
M7
M9
N10
N12
N14
DVDD
N19
S
3.3-V
3.3
V supply
su ly voltage
S
1 9 V supply
1.9-V
s ppl voltage
oltage
N3
N8
P11
P13
P9
U19
U3
W14
W8
A12
A13
B10
B12
B6
D15
D16
F10
F14
F8
CVDD
G13
G7
G8
K4
M3
M4
A3
A5
A7
A16
† I = Input, O = Output, Z = High Impedance, S = Supply Voltage, GND = Ground
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Signal Descriptions (Continued)
SIGNAL
NAME
NO.
TYPE†
DESCRIPTION
SUPPLY VOLTAGE PINS (CONTINUED)
A18
AA4
AA6
AA15
AA17
AA19
B2
B4
B19
C1
C3
C20
D2
D21
E1
E6
E8
CVDD
E10
S
1 9 V supply
1.9-V
s ppl voltage
oltage
E12
E14
E16
F5
F17
F21
G1
H5
H17
K5
K17
M5
M17
P5
P17
R21
† I = Input, O = Output, Z = High Impedance, S = Supply Voltage, GND = Ground
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Signal Descriptions (Continued)
SIGNAL
NAME
NO.
TYPE†
DESCRIPTION
SUPPLY VOLTAGE PINS (CONTINUED)
T1
T5
T17
U6
U8
U10
U12
U14
U16
U21
V1
V20
W2
W19
W21
Y3
Y18
Y20
CVDD
AA11
S
1.9-V
1.9
V supply
su ly voltage
AA12
F20
G18
H16
H18
L18
L19
L20
N20
P18
P19
R10
R14
U4
V11
V12
V15
W13
† I = Input, O = Output, Z = High Impedance, S = Supply Voltage, GND = Ground
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Signal Descriptions (Continued)
SIGNAL
NAME
NO.
TYPE†
DESCRIPTION
GROUND PINS
C11
C16
C6
D5
G3
H10
H12
H14
H7
H8
J11
J13
J7
J9
K8
L7
L9
M8
N7
VSS
R3
GND
Ground pins
ins
A4
A6
A8
A15
A17
A19
AA3
AA5
AA7
AA14
AA16
AA18
B3
B18
B20
C2
C19
C21
D1
† I = Input, O = Output, Z = High Impedance, S = Supply Voltage, GND = Ground
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Signal Descriptions (Continued)
SIGNAL
NAME
NO.
TYPE†
DESCRIPTION
GROUND PINS (CONTINUED)
D20
E5
E7
E9
E11
E13
E15
E17
E21
F1
G5
G17
G21
H1
J5
J17
L5
VSS
L17
GND
Ground pins
ins
N5
N17
P21
R1
R5
R17
T21
U1
U5
U7
U9
U11
U13
U15
U17
V2
V21
† I = Input, O = Output, Z = High Impedance, S = Supply Voltage, GND = Ground
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Signal Descriptions (Continued)
SIGNAL
NAME
NO.
TYPE†
DESCRIPTION
GROUND PINS (CONTINUED)
W1
W3
W20
Y2
Y4
Y19
F18
G19
H15
J15
J16
K10
K12
K14
L11
L13
L15
VSS
M10
GND
Ground pins
ins
M12
M14
N11
N13
N15
N9
P10
P12
P14
P15
P7
P8
R19
T4
W11
W16
W6
† I = Input, O = Output, Z = High Impedance, S = Supply Voltage, GND = Ground
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Signal Descriptions (Continued)
SIGNAL
NAME
NO.
TYPE†
DESCRIPTION
REMAINING UNCONNECTED PINS
D13
D14
D18
D3
D6
F12
G12
G15
NC
H19
H20
Unconnected pins
H21
L16
M16
M19
V19
V4
W18
W4
† I = Input, O = Output, Z = High Impedance, S = Supply Voltage, GND = Ground
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development support
Texas Instruments (TI) offers an extensive line of development tools for the ’C6x generation of DSPs, including
tools to evaluate the performance of the processors, generate code, develop algorithm implementations, and
fully integrate and debug software and hardware modules.
The following products support development of ’C6x-based applications:
Software-Development Tools:
Assembly optimizer
Assembler/Linker
Simulator
Optimizing ANSI C compiler
Application algorithms
C/Assembly debugger and code profiler
Hardware-Development Tools:
Extended development system (XDS) emulator (supports ’C6x multiprocessor system debug)
EVM (Evaluation Module)
The TMS320 DSP Development Support Reference Guide (SPRU011) contains information about
development-support products for all TMS320 family member devices, including documentation. See this
document for further information on TMS320 documentation or any TMS320 support products from Texas
Instruments. An additional document, the TMS320 Third-Party Support Reference Guide (SPRU052), contains
information about TMS320-related products from other companies in the industry. To receive TMS320 literature,
contact the Literature Response Center at 800/477-8924.
See Table 2 for a complete listing of development-support tools for the ’C6x. For information on pricing and
availability, contact the nearest TI field sales office or authorized distributor.
Table 2. SMJ320C6x Development-Support Tools
DEVELOPMENT TOOL
PLATFORM
PART NUMBER
Software
Ada 95 Compiler†
Sun Solaris 2.3‡
AD0345AS8500RF - Single User
AD0345BS8500RF - Multi-user
C Compiler/Assembler/Linker/Assembly Optimizer
Win32
TMDX3246855-07
C Compiler/Assembler/Linker/Assembly Optimizer
SPARC Solaris
TMDX3246555-07
Simulator
Win32
TMDS3246851-07
Simulator
SPARC Solaris
TMDS3246551-07
Win32, Windows NT
TMDX324016X-07
XDS510 Debugger/Emulation Software
Hardware
XDS510 Emulator§
PC
XDS510WS Emulator¶
SCSI
TMDS00510
TMDS00510WS
Software/Hardware
EVM Evaluation Kit
PC/Win95/Windows NT
TMDX3260A6201
EVM Evaluation Kit (including TMDX3246855–07)
PC/Win95/Windows NT
TMDX326006201
† Contact IRVINE Compiler Corporation (949) 250-1366 to order.
‡ NT support estimated availability 1Q00.
§ Includes XDS510 board and JTAG emulation cable. TMDX324016X-07 C-source Debugger/Emulation software is not included.
¶ Includes XDS510WS box, SCSI cable, power supply, and JTAG emulation cable.
XDS, XDS510, and XDS510WS are trademarks of Texas Instruments Incorporated.
Win32 and Windows NT are trademarks of Microsoft Corporation.
SPARC is a trademark of SPARC International, Inc.
Solaris is a trademark of Sun Microsystems, Inc.
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device and development-support tool nomenclature
To designate the stages in the product-development cycle, TI assigns prefixes to the part numbers of all SMJ320
devices and support tools. Each SMJ320 member has one of three prefixes: SMX, SM, or SMJ. Texas
Instruments recommends two of three possible prefix designators for support tools: TMDX and TMDS. These
prefixes represent evolutionary stages of product development from engineering prototypes (SMX/TMDX)
through fully qualified production devices/tools (SMJ/TMDS).
Device development evolutionary flow:
SMX
Experimental device that is not necessarily representative of the final device’s electrical
specifications
SM
Final silicon die that conforms to the device’s electrical specifications but has not completed
quality and reliability verification
SMJ
Fully qualified production device processed to MIL-PRF-38535
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
SMX devices and TMDX development-support tools are shipped against the following disclaimer:
“Developmental product is intended for internal evaluation purposes.”
SMJ devices and TMDS development-support tools have been characterized fully, and the quality and reliability
of the device have been demonstrated fully. TI’s standard warranty applies.
Predictions show that prototype devices (SMX or SM) 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, GLP), the temperature range, and the device speed range in megahertz (for example, 16 is
167 MHz). Figure 4 provides a legend for reading the complete device name for any SMJ320 family member.
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device and development-support tool nomenclature (continued)
SMJ 320
C 6701
GLP
W
14
PREFIX
SMX= Experimental device
SMJ = MIL-PRF-38535, QML
SM = Commercial
processing
DEVICE SPEED RANGE
14 = 140 MHz
16 = 167 MHz
TEMPERATURE RANGE (DEFAULT: 0°C TO 90°C)
S
= –40°C to 90°C, extended temperature
W
= –55°C to 115°C, extended temperature
DEVICE FAMILY
320 = SMJ320 family
TECHNOLOGY
C = CMOS
PACKAGE TYPE†
GLP = 429-pin ceramic BGA
DEVICE
’6x DSP:
† BGA =
6201B
6203
6701
Ball Grid Array
Figure 4. SMJ320 Device Nomenclature (Including SMJ320C6701)
documentation support
Extensive documentation supports all SMJ320 family generations of devices from product announcement
through applications development. The types of documentation available include: data sheets, such as this
document, with design specifications; complete user’s reference guides for all devices; technical briefs;
development-support tools; and hardware and software applications. The following is a brief, descriptive list of
support documentation specific to the ’C6x devices:
The TMS320C6000 CPU and Instruction Set Reference Guide (literature number SPRU189) describes the
’C6000 CPU architecture, instruction set, pipeline, and associated interrupts.
The TMS320C6000 Peripherals Reference Guide (literature number SPRU190) describes the functionality of
the peripherals available on ’C6x devices, such as the external memory interface (EMIF), host-port interface
(HPI), multichannel buffered serial ports (McBSPs), direct-memory-access (DMA), enhanced
direct-memory-access (EDMA) controller, expansion bus (XB), clocking and phase-locked loop (PLL); and
power-down modes. This guide also includes information on internal data and program memories.
The TMS320C6000 Programmer’s Guide (literature number SPRU198) describes ways to optimize C and
assembly code for ’C6x devices and includes application program examples.
The TMS320C6x C Source Debugger User’s Guide (literature number SPRU188) describes how to invoke the
’C6x simulator and emulator versions of the C source debugger interface and discusses various aspects of the
debugger, including: command entry, code execution, data management, breakpoints, profiling, and analysis.
The TMS320C6x Peripheral Support Library Programmer’s Reference (literature number SPRU273) describes
the contents of the ’C6x peripheral support library of functions and macros. It lists functions and macros both
by header file and alphabetically, provides a complete description of each, and gives code examples to show
how they are used.
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documentation support (continued)
TMS320C6000 Assembly Language Tools User’s Guide (literature number SPRU186) describes the assembly
language tools (assembler, linker, and other tools used to develop assembly language code), assembler
directives, macros, common object file format, and symbolic debugging directives for the ’C6000 generation of
devices.
The TMS320C6x Evaluation Module Reference Guide (literature number SPRU269) provides instructions for
installing and operating the ’C6x evaluation module. It also includes support software documentation,
application programming interfaces, and technical reference material.
TMS320C6000 DSP/BIOS User’s Guide (literature number SPRU303) describes how to use DSP/BIOS tools
and APIs to analyze embedded real-time DSP applications.
Code Composer User’s Guide (literature number SPRU296) explains how to use the Code Composer
development environment to build and debug embedded real-time DSP applications.
Code Composer Studio Tutorial (literature number SPRU301) introduces the Code Composer Studio integrated
development environment and software tools.
The TMS320C6000 Technical Brief (literature number SPRU197) gives an introduction to the ’C62x/C67x
devices, associated development tools, and third-party support.
A series of DSP textbooks is published by Prentice-Hall and John Wiley & Sons to support DSP research and
education. The TMS320 newsletter, Details on Signal Processing, is published quarterly and distributed to
update SMJ320 customers on product information. The TMS320 DSP bulletin board service (BBS) provides
access to information pertaining to the SMJ320 family, including documentation, source code, and object code
for many DSP algorithms and utilities. The BBS can be reached at 281/274-2323.
Information regarding TI DSP products is also available on the Worldwide Web at http://www.ti.com uniform
resource locator (URL).
clock PLL
All of the internal ’C67x clocks are generated from a single source through the CLKIN pin. This source clock
either drives the PLL, which multiplies the source clock in frequency to generate the internal CPU clock, or
bypasses the PLL to become the internal CPU clock.
To use the PLL to generate the CPU clock, the external PLL filter circuit must be properly designed. Table 3,
Table 4, and Figure 5 show the external PLL circuitry for either x1 (PLL bypass) or x4 PLL multiply modes.
Table 3 and Figure 6 show the external PLL circuitry for a system with ONLY x1 (PLL bypass) mode.
To minimize the clock jitter, a single clean power supply should power both the ’C67x device and the external
clock oscillator circuit. Noise coupling into PLLF will directly impact PLL clock jitter. The minimum CLKIN rise
and fall times should also be observed. For the input clock timing requirements, see the input and output clocks
electricals section. Guidelines for EMI filter selection are as follows: maximum attenuation frequency =
20-30 MHz, maximum dB attenuation = 45-50 dB, and minimum dB attenuation above 30 MHz = 20 dB.
Table 3. CLKOUT1 Frequency Ranges†
PLLFREQ3
(C13)
PLLFREQ2
(G11)
PLLFREQ1
(F11)
CLKOUT1 Frequency Range
(MHz)
0
0
0
50–140
0
0
1
65–167
0
1
0
130–167
† Due to overlap of frequency ranges when choosing the PLLFREQ, more than one frequency range can contain
the CLKOUT1 frequency. Choose the lowest frequency range that includes the desired frequency. For example,
for CLKOUT1 = 133 MHz, choose PLLFREQ value of 000b. For CLKOUT1 = 167 MHz, choose PLLFREQ value
of 001b. PLLFREQ values other than 000b, 001b, and 010b are reserved.
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clock PLL (continued)
Table 4. ’C6701 PLL Component Selection Table
CLKIN
RANGE
(MHz)
CLKMODE
CPU CLOCK
FREQUENCY
(CLKOUT1)
RANGE (MHz)
CLKOUT2
RANGE
(MHz)
R1
(Ω)
C1
(nF)
C2
(pF)
TYPICAL
LOCK TIME
(µs)‡
x4
12.5–41.7
50–167
25–83.5
60.4
27
560
75
‡ Under some operating conditions, the maximum PLL lock time may vary as much as 150% from the specified typical value. For example, if the
typical lock time is specified as 100 µs, the maximum value may be as long as 250 µs.
PLLFREQ3
PLLFREQ2
PLLFREQ1
3.3V
(see Table 3)
EMI Filter
PLLV
C3
10 mF
C4
0.1 mF
CLKMODE0
CLKMODE1
Internal to ’C6701
PLL
PLLMULT
PLLCLK
CLKIN
CLKIN
1
LOOP FILTER
CPU Clock
Frequency
f(CPUCLOCK)
CLKMODE1
CLKMODE0
PLL Multiply
Factors
0
0
x1(BYPASS)
1 x f(CLKIN)
0
1
Reserved
Reserved
1
0
Reserved
Reserved
1
1
x4
4 x f(CLKIN)
C2
C1
CPU
CLOCK
PLLG
Available Multiply Factors
PLLF
0
R1
NOTES: A. Keep the lead length and the number of vias between the PLLF pin, the PLLG pin, and R1, C1, and C2 to a minimum. In addition,
place all PLL external components (R1, C1, C2, C3, C4, and the EMI Filter) as close to the ’C6000 device as possible. For the best
performance, TI recommends that all the PLL external components be on a single side of the board without jumpers, switches, or
components other than the ones shown.
B. For reduced PLL jitter, maximize the spacing between switching signals and the PLL external components (R1, C1, C2, C3, C4,
and the EMI Filter).
C. The 3.3-V supply for the EMI filter must be from the same 3.3-V power plane supplying the I/O voltage, DVDD.
Figure 5. External PLL Circuitry for Either PLL x4 Mode or x1 (Bypass) Mode
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clock PLL (continued)
PLLFREQ3
PLLFREQ2
PLLFREQ1
3.3V
(see Table 3)
PLLV
CLKMODE0
CLKMODE1
Internal to ’C6701
PLLMULT
PLL
PLLCLK
CLKIN
CLKIN
LOOP FILTER
1
CPU
CLOCK
PLLG
PLLF
0
NOTES: A. For a system with ONLY PLL x1 (bypass) mode, short the PLLF terminal to the PLLG terminal.
B. The 3.3-V supply for the EMI filter must be from the same 3.3-V power plane supplying the I/O voltage, DVDD.
Figure 6. External PLL Circuitry for x1 (Bypass) Mode Only
power-supply sequencing
TI DSPs do not require specific power sequencing between the core supply and the I/O supply. However,
systems should be designed to ensure that neither supply is powered up for extended periods of time if the other
supply is below the proper operating voltage.
system-level design considerations
System-level design considerations, such as bus contention, may require supply sequencing to be
implemented. In this case, the core supply should be powered up at the same time as, or prior to (and powered
down after), the I/O buffers. This is to ensure that the I/O buffers receive valid inputs from the core before the
output buffers are powered up, thus, preventing bus contention with other chips on the board.
power-supply design considerations
For systems using the C6000 DSP platform of devices, the core supply may be required to provide in excess
of 2 A per DSP until the I/O supply is powered up. This extra current condition is a result of uninitialized logic
within the DSP(s) and is corrected once the CPU sees an internal clock pulse. With the PLL enabled, as the
I/O supply is powered on, a clock pulse is produced stopping the extra current draw from the supply. With the
PLL disabled, an external clock pulse may be required to stop this extra current draw. A normal current state
returns once the I/O power supply is turned on and the CPU sees a clock pulse. Decreasing the amount of time
between the core supply power up and the I/O supply power up can minimize the effects of this current draw.
A dual-power supply with simultaneous sequencing, such as available with TPS563xx controllers or PT69xx
plug-in power modules, can be used to eliminate the delay between core and I/O power up [see the Using the
TPS56300 to Power DSPs application report (literature number SLVA088)]. A Schottky diode can also be used
to tie the core rail to the I/O rail, effectively pulling up the I/O power supply to a level that can help initialize the
logic within the DSP.
Core and I/O supply voltage regulators should be located close to the DSP (or DSP array) to minimize
inductance and resistance in the power delivery path. Additionally, when designing for high-performance
applications utilizing the C6000 platform of DSPs, the PC board should include separate power planes for
core, I/O, and ground, all bypassed with high-quality low-ESL/ESR capacitors.
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absolute maximum ratings over operating case temperature range (unless otherwise noted)†
Supply voltage range, CVDD (see Note 1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to 2.3 V
Supply voltage range, DVDD (see Note 1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to 4 V
Input voltage range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to 4 V
Output voltage range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to 4 V
Operating case temperature range, TC S suffix device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –40_C to 90_C
W suffix device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –55_C to 115_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.
NOTE 1: All voltage values are with respect to VSS.
recommended operating conditions
MIN
NOM
MAX
UNIT
CVDD
Supply voltage
1.81
1.9
1.99
V
DVDD
Supply voltage
3.14
3.30
3.46
V
VSS
VIH
Supply ground
0
0
0
V
VIL
IOH
Low-level input voltage
0.8
V
High-level output current
–12
mA
IOL
Low-level output current
12
mA
TC
Case temperature
High-level input voltage
2.0
POST OFFICE BOX 1443
V
S suffix device
–40
90
W suffix device
–55
115
• HOUSTON, TEXAS 77251–1443
_C
27
SGUS030B – APRIL 2000 – REVISED MAY 2001
electrical characteristics over recommended ranges of supply voltage and operating case
temperature (unless otherwise noted)
PARAMETER
VOH
VOL
II
IOZ
TEST CONDITIONS
High-level output voltage
DVDD = MIN,
Low-level output voltage
Input current†
DVDD = MIN,
IOH = MAX
IOL = MAX
MIN
TYP
UNIT
V
VI = VSS to DVDD
VO = DVDD or 0 V
Off-state output current
MAX
2.4
0.6
V
±10
uA
±10
uA
IDD2V
Supply current, CPU + CPU memory access‡
CVDD = NOM,
CPU clock = 150 MHz
470
mA
IDD2V
Supply current, peripherals§
CVDD = NOM,
CPU clock = 150 MHz
250
mA
IDD3V
Supply current, I/O pins¶
DVDD = NOM,
CPU clock = 150 MHz
85
mA
Ci
Input capacitance
*15
pF
Co
Output capacitance
*15
pF
* This parameter is not tested.
† TMS and TDI are not included due to internal pullups.
TRST is not included due to internal pulldown.
‡ Measured with average CPU activity:
50% of time:
8 instructions per cycle, 32-bit DMEM access per cycle
50% of time:
2 instructions per cycle, 16-bit DMEM access per cycle
§ Measured with average peripheral activity:
50% of time:
Timers at max rate, McBSPs at E1 rate, and DMA burst transfer between DMEM and SDRAM
50% of time:
Timers at max rate, McBSPs at E1 rate, and DMA servicing McBSPs
¶ Measured with average I/O activity (30-pF load, SDCLK on):
25% of time:
Reads from external SDRAM
25% of time:
Writes to external SDRAM
50% of time:
No activity
28
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
SGUS030B – APRIL 2000 – REVISED MAY 2001
PARAMETER MEASUREMENT INFORMATION
IOL
Tester Pin
Electronics
50 Ω
Vref
Output
Under
Test
CT = 30 pF†
IOH
† Typical distributed load circuit capacitance.
signal-transition levels
All input and output timing parameters are referenced to 1.5 V for both “0” and “1” logic levels.
Vref = 1.5 V
Figure 7. Input and Output Voltage Reference Levels for ac Timing Measurements
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
29
SGUS030B – APRIL 2000 – REVISED MAY 2001
INPUT AND OUTPUT CLOCKS
timing requirements for CLKIN† (see Figure 8)
’C6701-14
CLKMODE = x4
NO.
MIN
1
’C6701-16
CLKMODE = x1
MAX
MIN
CLKMODE = x4
MAX
MIN
CLKMODE = x1
MAX
MIN
UNIT
MAX
tc(CLKIN)
Cycle time, CLKIN
28.4
7.1
24
6
ns
2
tw(CLKINH)
Pulse duration,
CLKIN high
*0.4C‡
*0.45C‡
*0.4C‡
*0.45C‡
ns
3
tw(CLKINL)
Pulse duration,
CLKIN low
*0.4C‡
*0.45C‡
*0.4C‡
*0.45C‡
ns
4
tt(CLKIN)
Transition time, CLKIN
*5
*0.6
*5
† The reference points for the rise and fall transitions are measured at 20% and 80%, respectively, of VIH.
‡ C = CLKIN cycle time in ns. For example, when CLKIN frequency is 10 MHz, use C = 100 ns.
*This parameter is not tested.
1
*0.6
ns
4
2
CLKIN
3
4
Figure 8. CLKIN Timings
switching characteristics for CLKOUT1‡§ (see Figure 9)
’C6701-14
’C6701-16
NO
NO.
1
2
3
PARAMETER
CLKMODE = x4
MIN
MAX
MIN
MAX
*P – 0.7
*P + 0.7
*P – 0.7
*P + 0.7
ns
Pulse duration, CLKOUT1 high
*(P/2) – 0.5
*(P/2) + 0.5
*PH – 0.5
*PH + 0.5
ns
Pulse duration, CLKOUT1 low
*(P/2) – 0.5
*(P/2) + 0.5
*PL – 0.5
*PL + 0.5
ns
*0.6
ns
tc(CKO1)
tw(CKO1H)
Cycle time, CLKOUT1
tw(CKO1L)
tt(CKO1)
4
Transition time, CLKOUT1
‡ P = 1/CPU clock frequency in nanoseconds (ns).
§ PH is the high period of CLKIN in ns and PL is the low period of CLKIN in ns.
*This parameter is not tested.
*0.6
1
4
2
CLKOUT1
3
4
Figure 9. CLKOUT1 Timings
30
UNIT
CLKMODE = x1
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
SGUS030B – APRIL 2000 – REVISED MAY 2001
INPUT AND OUTPUT CLOCKS (CONTINUED)
switching characteristics for CLKOUT2† (see Figure 10)
NO.
1
2
3
4
’C6701-14
’C6701-16
PARAMETER
UNIT
MIN
MAX
tc(CKO2)
tw(CKO2H)
Cycle time, CLKOUT2
*2P – 0.7
*2P + 0.7
ns
Pulse duration, CLKOUT2 high
*P – 0.7
*P + 0.7
ns
tw(CKO2L)
tt(CKO2)
Pulse duration, CLKOUT2 low
*P – 0.7
*P + 0.7
ns
*0.6
ns
Transition time, CLKOUT2
† P = 1/CPU clock frequency in ns.
*This parameter is not tested.
1
4
2
CLKOUT2
3
4
Figure 10. CLKOUT2 Timings
SDCLK, SSCLK timing parameters
SDCLK timing parameters are the same as CLKOUT2 parameters.
SSCLK timing parameters are the same as CLKOUT1 or CLKOUT2 parameters, depending on SSCLK
configuration.
switching characteristics for the relation of SSCLK, SDCLK, and CLKOUT2 to CLKOUT1
(see Figure 11)
NO.
1
’C6701-14
’C6701-16
PARAMETER
MIN
MAX
UNIT
td(CKO1-SSCLK)
td(CKO1-SSCLK1/2)
Delay time, CLKOUT1 edge to SSCLK edge
–0.8
3.4
ns
2
Delay time, CLKOUT1 edge to SSCLK edge (1/2 clock rate)
–1.0
3.0
ns
3
td(CKO1-CKO2)
Delay time, CLKOUT1 edge to CLKOUT2 edge
–1.5
2.5
ns
4
td(CKO1-SDCLK)
Delay time, CLKOUT1 edge to SDCLK edge
–1.5
1.9
ns
CLKOUT1
1
SSCLK
2
SSCLK (1/2rate)
3
CLKOUT2
4
SDCLK
Figure 11. Relation of CLKOUT2, SDCLK, and SSCLK to CLKOUT1
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
31
SGUS030B – APRIL 2000 – REVISED MAY 2001
ASYNCHRONOUS MEMORY TIMING
timing requirements for asynchronous memory cycles† (see Figure 12 and Figure 13)
’C6701-14
’C6701-16
NO.
MIN
6
7
10
11
UNIT
MAX
tsu(EDV-CKO1H)
th(CKO1H-EDV)
Setup time, read EDx valid before CLKOUT1 high
4.8
ns
Hold time, read EDx valid after CLKOUT1 high
1.5
ns
tsu(ARDY-CKO1H)
th(CKO1H-ARDY)
Setup time, ARDY valid before CLKOUT1 high
3.5
ns
Hold time, ARDY valid after CLKOUT1 high
1.5
ns
† To ensure data setup time, simply program the strobe width wide enough. ARDY is internally synchronized. If ARDY does meet setup or hold
time, it may be recognized in the current cycle or the next cycle. Thus, ARDY can be an asynchronous input.
switching characteristics for asynchronous memory cycles‡ (see Figure 12 and Figure 13)
NO.
1
2
3
4
5
8
9
12
13
14
PARAMETER
UNIT
MIN
MAX
–1.0
4.5
ns
4.5
ns
td(CKO1H-CEV)
td(CKO1H-BEV)
Delay time, CLKOUT1 high to CEx valid
td(CKO1H-BEIV)
td(CKO1H-EAV)
Delay time, CLKOUT1 high to BEx invalid
td(CKO1H-EAIV)
td(CKO1H-AOEV)
Delay time, CLKOUT1 high to EAx invalid
–1.0
Delay time, CLKOUT1 high to AOE valid
–1.0
4.5
ns
td(CKO1H-AREV)
td(CKO1H-EDV)
Delay time, CLKOUT1 high to ARE valid
–1.0
4.5
ns
4.5
ns
td(CKO1H-EDIV)
td(CKO1H-AWEV)
Delay time, CLKOUT1 high to EDx invalid
–1.0
Delay time, CLKOUT1 high to AWE valid
–1.0
Delay time, CLKOUT1 high to BEx valid
–1.0
Delay time, CLKOUT1 high to EAx valid
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
ns
4.5
Delay time, CLKOUT1 high to EDx valid
‡ The minimum delay is also the minimum output hold after CLKOUT1 high.
32
’C6701-14
’C6701-16
ns
ns
ns
4.5
ns
SGUS030B – APRIL 2000 – REVISED MAY 2001
ASYNCHRONOUS MEMORY TIMING (CONTINUED)
Setup = 2
Not ready = 2
Strobe = 5
HOLD = 1
CLKOUT1
1
1
2
3
4
5
CEx
BE[3:0]
EA[21:2]
7
6
ED[31:0]
8
8
AOE
9
9
ARE
AWE
11
11
10
10
ARDY
Figure 12. Asynchronous Memory Read Timing
Setup = 2
Not ready = 2
Strobe = 5
HOLD = 1
CLKOUT1
1
1
2
3
4
5
CEx
BE[3:0]
EA[21:2]
12
13
ED[31:0]
AOE
ARE
14
14
AWE
11
10
11
10
ARDY
Figure 13. Asynchronous Memory Write Timing
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
33
SGUS030B – APRIL 2000 – REVISED MAY 2001
SYNCHRONOUS-BURST MEMORY TIMING
timing requirements for synchronous-burst SRAM cycles (full-rate SSCLK)
(see Figure 14)
NO
NO.
7
8
tsu(EDV-SSCLKH)
th(SSCLKH-EDV)
’C6701-14
’C6701-16
MIN
MIN
MAX
MAX
UNIT
Setup time, read EDx valid before SSCLK high
2.6
2.5
ns
Hold time, read EDx valid after SSCLK high
1.5
1.5
ns
switching characteristics for synchronous-burst SRAM cycles† (full-rate SSCLK)
(see Figure 14 and Figure 15)
NO
NO.
1
PARAMETER
’C6701-14
’C6701-16
MIN
MIN
MAX
MAX
UNIT
tosu(CEV-SSCLKH)
toh(SSCLKH-CEV)
Output setup time, CEx valid before SSCLK high
0.5P – 1.5
0.5P – 1.3
ns
Output hold time, CEx valid after SSCLK high
0.5P – 2.5
0.5P – 2.3
ns
tosu(BEV-SSCLKH)
toh(SSCLKH-BEIV)
Output setup time, BEx valid before SSCLK high
0.5P – 1.6
0.5P – 1.6
ns
Output hold time, BEx invalid after SSCLK high
0.5P – 2.5
0.5P – 2.3
ns
tosu(EAV-SSCLKH)
toh(SSCLKH-EAIV)
Output setup time, EAx valid before SSCLK high
0.5P – 1.7
0.5P – 1.7
ns
Output hold time, EAx invalid after SSCLK high
0.5P – 2.5
0.5P – 2.5
ns
tosu(ADSV-SSCLKH)
toh(SSCLKH-ADSV)
Output setup time, SSADS valid before SSCLK high
0.5P – 1.5
0.5P – 1.3
ns
Output hold time, SSADS valid after SSCLK high
0.5P – 2.5
0.5P – 2.3
ns
tosu(OEV-SSCLKH)
toh(SSCLKH-OEV)
Output setup time, SSOE valid before SSCLK high
0.5P – 1.5
0.5P – 1.3
ns
Output hold time, SSOE valid after SSCLK high
0.5P – 2.5
0.5P – 2.5
ns
tosu(EDV-SSCLKH)
toh(SSCLKH-EDIV)
Output setup time, EDx valid before SSCLK high
0.5P – 1.5
0.5P – 1.3
ns
14
Output hold time, EDx invalid after SSCLK high
0.5P – 2.5
0.5P – 2.5
ns
15
tosu(WEV-SSCLKH)
Output setup time, SSWE valid before SSCLK high
0.5P – 1.5
0.5P – 1.3
ns
2
3
4
5
6
9
10
11
12
13
16
toh(SSCLKH-WEV)
Output hold time, SSWE valid after SSCLK high
0.5P – 2.5
0.5P – 2.3
ns
† The effects of internal clock jitter are included at test. There is no need to adjust timing numbers for internal clock jitter.
When the PLL is used (CLKMODE x4), P = 1/CPU clock frequency in ns. For example, when running parts at 167 MHz, use P = 6 ns.
For CLKMODE x1, 0.5P is defined as PH (pulse duration of CLKIN high) for all output setup times; 0.5P is defined as PL (pulse duration of CLKIN
low) for all output hold times.
34
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
SGUS030B – APRIL 2000 – REVISED MAY 2001
SYNCHRONOUS-BURST MEMORY TIMING (CONTINUED)
SSCLK
1
2
CEx
3
BE[3:0]
BE1
BE2
BE3
4
BE4
A1
A2
A3
6
A4
5
EA[21:2]
8
7
Q1
ED[31:0]
9
Q2
Q3
Q4
10
SSADS
11
12
SSOE
SSWE
Figure 14. SBSRAM Read Timing (Full-Rate SSCLK)
SSCLK
1
2
CEx
3
BE[3:0]
BE1
BE2
BE3
4
BE4
A1
A2
A3
6
A4
D3
14
D4
5
EA[21:2]
13
ED[31:0]
D1
D2
9
10
15
16
SSADS
SSOE
SSWE
Figure 15. SBSRAM Write Timing (Full-Rate SSCLK)
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
35
SGUS030B – APRIL 2000 – REVISED MAY 2001
SYNCHRONOUS-BURST MEMORY TIMING (CONTINUED)
timing requirements for synchronous-burst SRAM cycles (half-rate SSCLK) (see Figure 16)
NO
NO.
7
8
tsu(EDV-SSCLKH)
th(SSCLKH-EDV)
’C6701-14
’C6701-16
MIN
MIN
MAX
MAX
UNIT
Setup time, read EDx valid before SSCLK high
3.8
3.8
ns
Hold time, read EDx valid after SSCLK high
1.5
1.5
ns
switching characteristics for synchronous-burst SRAM cycles† (half-rate SSCLK)
(see Figure 16 and Figure 17)
NO
NO.
1
PARAMETER
’C6701-14
’C6701-16
MIN
MIN
MAX
MAX
UNIT
tosu(CEV-SSCLKH)
toh(SSCLKH-CEV)
Output setup time, CEx valid before SSCLK high
1.5P – 5.5
1.5P – 4.5
ns
Output hold time, CEx valid after SSCLK high
0.5P – 2.3
0.5P – 2
ns
tosu(BEV-SSCLKH)
toh(SSCLKH-BEIV)
Output setup time, BEx valid before SSCLK high
1.5P – 5.5
1.5P – 4.5
ns
Output hold time, BEx invalid after SSCLK high
0.5P – 2.3
0.5P – 2
ns
tosu(EAV-SSCLKH)
toh(SSCLKH-EAIV)
Output setup time, EAx valid before SSCLK high
1.5P – 5.5
1.5P – 4.5
ns
Output hold time, EAx invalid after SSCLK high
0.5P – 2.3
0.5P – 2
ns
tosu(ADSV-SSCLKH)
toh(SSCLKH-ADSV)
Output setup time, SSADS valid before SSCLK high
1.5P – 5.5
1.5P – 4.5
ns
Output hold time, SSADS valid after SSCLK high
0.5P – 2.3
0.5P – 2
ns
tosu(OEV-SSCLKH)
toh(SSCLKH-OEV)
Output setup time, SSOE valid before SSCLK high
1.5P – 5.5
1.5P – 4.5
ns
Output hold time, SSOE valid after SSCLK high
0.5P – 2.3
0.5P – 2
ns
tosu(EDV-SSCLKH)
toh(SSCLKH-EDIV)
Output setup time, EDx valid before SSCLK high
1.5P – 5.5
1.5P – 4.5
ns
14
Output hold time, EDx invalid after SSCLK high
0.5P – 2.3
0.5P – 2.2
ns
15
tosu(WEV-SSCLKH)
Output setup time, SSWE valid before SSCLK high
1.5P – 5.5
1.5P – 4.5
ns
2
3
4
5
6
9
10
11
12
13
16
toh(SSCLKH-WEV)
Output hold time, SSWE valid after SSCLK high
0.5P – 2.3
0.5P – 2
ns
† The effects of internal clock jitter are included at test. There is no need to adjust timing numbers for internal clock jitter.
When the PLL is used (CLKMODE x4), P = 1/CPU clock frequency in ns. For example, when running parts at 167 MHz, use P = 6 ns.
For CLKMODE x1:
1.5P = P + PH, where P = 1/CPU clock frequency, and PH = pulse duration of CLKIN high.
0.5P = PL, where PL = pulse duration of CLKIN low.
36
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
SGUS030B – APRIL 2000 – REVISED MAY 2001
SYNCHRONOUS-BURST MEMORY TIMING (CONTINUED)
SSCLK
1
2
CEx
BE[3:0]
3
BE1
BE2
BE3
BE4
4
EA[21:2]
5
A1
A2
A3
A4
6
7
Q1
ED[31:0]
8
Q2
9
Q3
Q4
10
SSADS
11
12
SSOE
SDWE
Figure 16. SBSRAM Read Timing (1/2 Rate SSCLK)
SSCLK
1
2
CEx
BE[3:0]
3
BE1
BE2
BE3
BE4
4
EA[21:2]
5
A1
A2
A3
A4
ED[31:0]
Q1
Q2
Q3
Q4
6
13
14
9
10
15
16
SSADS
SSOE
SSWE
Figure 17. SBSRAM Write Timing (1/2 Rate SSCLK)
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
37
SGUS030B – APRIL 2000 – REVISED MAY 2001
SYNCHRONOUS DRAM TIMING
timing requirements for synchronous DRAM cycles (see Figure 18)
NO
NO.
7
8
tsu(EDV-SDCLKH)
th(SDCLKH-EDV)
’C6701-14
’C6701-16
MIN
MIN
MAX
MAX
UNIT
Setup time, read EDx valid before SDCLK high
2
2
ns
Hold time, read EDx valid after SDCLK high
3
3
ns
switching characteristics for synchronous DRAM cycles† (see Figure 18–Figure 23)
NO
NO.
1
PARAMETER
tosu(CEV-SDCLKH)
toh(SDCLKH-CEV)
Output setup time, CEx valid before SDCLK high
tosu(BEV-SDCLKH)
toh(SDCLKH-BEIV)
Output setup time, BEx valid before SDCLK high
Output setup time, EAx valid before SDCLK high
6
tosu(EAV-SDCLKH)
toh(SDCLKH-EAIV)
9
tosu(SDCAS-SDCLKH)
10
11
toh(SDCLKH-SDCAS)
tosu(EDV-SDCLKH)
12
toh(SDCLKH-EDIV)
Output hold time, EDx invalid after SDCLK high
13
tosu(SDWE-SDCLKH)
Output setup time, SDWE valid before SDCLK
high
14
toh(SDCLKH-SDWE)
Output hold time, SDWE valid after SDCLK high
15
tosu(SDA10V-SDCLKH)
Output setup time, SDA10 valid before SDCLK
high
16
toh(SDCLKH-SDA10IV)
Output hold time, SDA10 invalid after SDCLK
high
17
tosu(SDRAS-SDCLKH)
Output setup time, SDRAS valid before SDCLK
high
2
3
4
5
’C6701-14
’C6701-16
MIN
MIN
MAX
MAX
UNIT
1.5P – 5
1.5P – 4
ns
0.5P – 1.9
0.5P – 1.5
ns
1.5P – 5
1.5P – 4
ns
0.5P – 1.9
0.5P – 1.5
ns
1.5P – 5
1.5P – 4
ns
Output hold time, EAx invalid after SDCLK high
0.5P – 1.9
0.5P – 1.5
ns
Output setup time, SDCAS valid before SDCLK
high
1.5P – 5
1.5P – 4
ns
Output hold time, SDCAS valid after SDCLK high
0.5P – 1.9
0.5P – 1.5
ns
Output setup time, EDx valid before SDCLK high
1.5P – 5
1.5P – 4
ns
0.5P – 1.9
0.5P – 1.5
ns
1.5P – 5
1.5P – 4
ns
0.5P – 1.9
0.5P – 1.5
ns
1.5P – 5
1.5P – 4
ns
0.5P – 1.9
0.5P – 1.5
ns
1.5P – 5
1.5P – 4
ns
Output hold time, CEx valid after SDCLK high
Output hold time, BEx invalid after SDCLK high
18
toh(SDCLKH-SDRAS)
Output hold time, SDRAS valid after SDCLK high
0.5P – 1.9
0.5P – 1.5
ns
† The effects of internal clock jitter are included at test. There is no need to adjust timing numbers for internal clock jitter.
When the PLL is used (CLKMODE x4), P = 1/CPU clock frequency in ns. For example, when running parts at 167 MHz, use P = 6 ns.
For CLKMODE x1:
1.5P = P + PH, where P = 1/CPU clock frequency, and PH = pulse duration of CLKIN high.
0.5P = PL, where PL = pulse duration of CLKIN low.
38
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
SGUS030B – APRIL 2000 – REVISED MAY 2001
SYNCHRONOUS DRAM TIMING (CONTINUED)
READ
READ
READ
SDCLK
1
2
CEx
3
BE[3:0]
5
EA[15:2]
4
BE1
BE2
CA2
CA3
BE3
6
CA1
7
8
D1
ED[31:0]
15
16
9
10
D2
D3
SDA10
SDRAS
SDCAS
SDWE
Figure 18. Three SDRAM Read Commands
WRITE
WRITE
WRITE
SDCLK
1
2
CEx
3
4
BE1
BE[3:0]
5
EA[15:2]
BE3
CA2
CA3
D2
D3
6
CA1
11
D1
ED[31:0]
BE2
12
15
16
9
10
13
14
SDA10
SDRAS
SDCAS
SDWE
Figure 19. Three SDRAM Write Commands
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
39
SGUS030B – APRIL 2000 – REVISED MAY 2001
SYNCHRONOUS DRAM TIMING (CONTINUED)
ACTV
SDCLK
1
2
CEx
BE[3:0]
5
Bank Activate/Row Address
EA[15:2]
ED[31:0]
15
Row Address
SDA10
17
18
SDRAS
SDCAS
SDWE
Figure 20. SDRAM ACTV Command
DCAB
SDCLK
1
2
15
16
17
18
CEx
BE[3:0]
EA[15:2]
ED[31:0]
SDA10
SDRAS
SDCAS
13
SDWE
Figure 21. SDRAM DCAB Command
40
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
14
SGUS030B – APRIL 2000 – REVISED MAY 2001
SYNCHRONOUS DRAM TIMING (CONTINUED)
REFR
SDCLK
1
2
CEx
BE[3:0]
EA[15:2]
ED[31:0]
SDA10
17
18
SDRAS
9
10
SDCAS
SDWE
Figure 22. SDRAM REFR Command
MRS
SDCLK
1
2
5
6
CEx
BE[3:0]
MRS Value
EA[15:2]
ED[31:0]
SDA10
17
18
9
10
13
14
SDRAS
SDCAS
SDWE
Figure 23. SDRAM MRS Command
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
41
SGUS030B – APRIL 2000 – REVISED MAY 2001
HOLD/HOLDA TIMING
timing requirements for the hold/hold acknowledge cycles† (see Figure 24)
’C6701-14
’C6701-16
NO.
MIN
1
2
tsu(HOLDH-CKO1H)
th(CKO1H-HOLDL)
Setup time, HOLD high before CLKOUT1 high
5
Hold time, HOLD low after CLKOUT1 high
2
UNIT
MAX
ns
ns
† HOLD is synchronized internally. Therefore, if setup and hold times are not met, it will either be recognized in the current cycle or in the next cycle.
Thus, HOLD can be an asynchronous input.
switching characteristics for the hold/hold acknowledge cycles‡ (see Figure 24)
NO.
’C6701-14
’C6701-16
PARAMETER
MIN
3
4
5
6
7
8
tR(HOLDL-EMHZ)
tR(EMHZ-HOLDAL)
Response time, HOLD low to EMIF high impedance
tR(HOLDH-HOLDAH)
td(CKO1H-HOLDAL)
Response time, HOLD high to HOLDA high
td(CKO1H-BHZ)
td(CKO1H-BLZ)
Delay time, CLKOUT1 high to EMIF Bus high impedance¶
Delay time, CLKOUT1 high to EMIF Bus low impedance¶
UNIT
MAX
§
ns
2P
ns
7P
ns
1
8
ns
*1
*8
ns
4P
Response time, EMIF high impedance to HOLDA low
4P
Delay time, CLKOUT1 high to HOLDA valid
*1
*12
ns
tR(HOLDH-BLZ)
Response time, HOLD high to EMIF Bus low impedance¶
3P
6P
ns
‡ P = 1/CPU clock frequency in ns. For example, when running parts at 167 MHz, use P = 6 ns.
§ All pending EMIF transactions are allowed to complete before HOLDA is asserted. The worst cases for this is an asynchronous read or write
with external ARDY used or a minimum of eight consecutive SDRAM reads or writes when RBTR8 = 1. If no bus transactions are occurring, then
the minimum delay time can be achieved. Also, bus hold can be indefinitely delayed by setting the NOHOLD = 1.
¶ EMIF Bus consists of CE[3:0], BE[3:0], ED[31:0], EA[21:2], ARE, AOE, AWE, SSADS, SSOE, SSWE, SDA10, SDRAS, SDCAS, and SDWE.
*This parameter is not tested.
9
DSP Owns Bus
External Requester
DSP Owns Bus
5
9
4
3
CLKOUT1
2
2
1
1
HOLD
6
6
HOLDA
7
8
EMIF Bus†
’C6701
Ext Req
’C6701
† EMIF Bus consists of CE[3:0], BE[3:0], ED[31:0], EA[21:2], ARE, AOE, AWE, SSADS, SSOE, SSWE, SDA10, SDRAS, SDCAS, and SDWE.
Figure 24. HOLD/HOLDA Timing
42
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
SGUS030B – APRIL 2000 – REVISED MAY 2001
RESET TIMING
timing requirements for reset (see Figure 25)
’C6701-14
’C6701-16
NO.
MIN
1
tw(RESET)
Width of the RESET pulse (PLL stable)†
UNIT
MAX
CLKOUT1
cycles
*10
*250
µs
† This parameter applies to CLKMODE x1 when CLKIN is stable and applies to CLKMODE x4 when CLKIN and PLL are stable.
*This parameter is not tested.
‡ This parameter only applies to CLKMODE x4. The RESET signal is not connected internally to the clock PLL circuit. The PLL, however, may
need up to 250 µs to stabilize following device powerup or after PLL configuration has been changed. During that time, RESET must be asserted
to ensure proper device operation. See the clock PLL section for PLL lock times.
Width of the RESET pulse (PLL needs to sync up)‡
switching characteristics during reset§ (see Figure 25)
NO.
’C6701-14
’C6701-16
PARAMETER
MIN
2
tR(RESET)
Response time to change of value in RESET signal
3
td(CKO1H-CKO2IV)
td(CKO1H-CKO2V)
Delay time, CLKOUT1 high to CLKOUT2 invalid
td(CKO1H-SDCLKIV)
td(CKO1H-SDCLKV)
Delay time, CLKOUT1 high to SDCLK invalid
td(CKO1H-SSCKIV)
td(CKO1H-SSCKV)
Delay time, CLKOUT1 high to SSCLK invalid
td(CKO1H-LOWIV)
td(CKO1H-LOWV)
Delay time, CLKOUT1 high to low group invalid
td(CKO1H-HIGHIV)
td(CKO1H-HIGHV)
Delay time, CLKOUT1 high to high group invalid
td(CKO1H-ZHZ)
td(CKO1H-ZV)
Delay time, CLKOUT1 high to Z group high impedance
4
5
6
7
8
9
10
11
12
13
14
§ Low group consists of:
High group consists of:
Z group consists of:
*–1
ns
*10
*–1
Delay time, CLKOUT1 high to SDCLK valid
*10
*10
ns
ns
*10
*–1
Delay time, CLKOUT1 high to high group valid
ns
ns
*–1
Delay time, CLKOUT1 high to low group valid
ns
ns
*–1
Delay time, CLKOUT1 high to SSCLK valid
Delay time, CLKOUT1 high to Z group valid
CLKOUT1
cycles
*1
Delay time, CLKOUT1 high to CLKOUT2 valid
UNIT
MAX
ns
ns
*10
*–1
ns
ns
*10
ns
IACK, INUM[3:0], DMAC[3:0], PD, TOUT0, and TOUT1.
HRDY and HINT.
EA[21:2], ED[31:0], CE[3:0], BE[3:0], ARE, AWE, AOE, SSADS, SSOE, SSWE, SDA10, SDRAS, SDCAS,
SDWE, HD[15:0], CLKX0, CLKX1, FSX0, FSX1, DX0, DX1, CLKR0, CLKR1, FSR0, and FSR1.
*This parameter is not tested.
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
43
SGUS030B – APRIL 2000 – REVISED MAY 2001
RESET TIMING (CONTINUED)
CLKOUT1
1
2
2
RESET
3
4
5
6
7
8
9
10
11
12
13
14
CLKOUT2
SDCLK
SSCLK
LOW GROUP†
HIGH GROUP†
Z GROUP†
† Low group consists of:
High group consists of:
Z group consists of:
IACK, INUM[3:0], DMAC[3:0], PD, TOUT0, and TOUT1.
HRDY and HINT.
EA[21:2], ED[31:0], CE[3:0], BE[3:0], ARE, AWE, AOE, SSADS, SSOE, SSWE, SDA10, SDRAS, SDCAS,
SDWE, HD[15:0], CLKX0, CLKX1, FSX0, FSX1, DX0, DX1, CLKR0, CLKR1, FSR0, and FSR1.
Figure 25. Reset Timing
44
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
SGUS030B – APRIL 2000 – REVISED MAY 2001
EXTERNAL INTERRUPT/RESET TIMING
timing requirements for interrupt response cycles†‡ (see Figure 26)
’C6701-14
’C6701-16
NO.
MIN
2
3
tw(ILOW)
tw(IHIGH)
Width of the interrupt pulse low
*2P
Width of the interrupt pulse high
*2P
UNIT
MAX
ns
ns
† Interrupt signals are synchronized internally and are potentially recognized one cycle later if setup and hold times are violated. Thus, they can
be connected to asynchronous inputs.
‡ P = 1/CPU clock frequency in ns. For example, when running parts at 167 MHz, use P = 6 ns.
*This parameter is not tested.
switching characteristics during interrupt response cycles§ (see Figure 26)
NO.
’C6701-14
’C6701-16
PARAMETER
MIN
1
Response time, EXT_INTx high to IACK high
4
tR(EINTH-IACKH)
td(CKO2L-IACKV)
5
td(CKO2L-INUMV)
Delay time, CLKOUT2 low to INUMx valid
UNIT
MAX
9P
Delay time, CLKOUT2 low to IACK valid
–0.5P
6
td(CKO2L-INUMIV) Delay time, CLKOUT2 low to INUMx invalid
§ P = 1/CPU clock frequency in ns. For example, when running parts at 167 MHz, use P = 6 ns.
When the PLL is used (CLKMODE x4), 0.5P = 1/(2 × CPU clock frequency).
For CLKMODE x1: 0.5P = PH, where PH is the high period of CLKIN.
ns
13 – 0.5P
ns
10 – 0.5P
ns
–0.5P
ns
1
CLKOUT2
2
3
EXT_INTx, NMI
Intr Flag
4
4
IACK
6
5
Interrupt Number
INUMx
Figure 26. Interrupt Timing
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
45
SGUS030B – APRIL 2000 – REVISED MAY 2001
HOST-PORT INTERFACE TIMING
timing requirements for host-port interface cycles†‡ (see Figure 27, Figure 28, Figure 29, and
Figure 30)
’C6701-14
’C6701-16
NO.
MIN
1
2
3
4
10
11
12
tsu(SEL-HSTBL)
th(HSTBL-SEL)
Setup time, select signals§ valid before HSTROBE low
Hold time, select signals§ valid after HSTROBE low
tw(HSTBL)
tw(HSTBH)
tsu(SEL-HASL)
th(HASL-SEL)
13
tsu(HDV-HSTBH)
th(HSTBH-HDV)
14
th(HRDYL-HSTBL)
18
tsu(HASL-HSTBL)
th(HSTBL-HASL)
19
UNIT
MAX
4
ns
2
ns
Pulse duration, HSTROBE low
*2P
ns
Pulse duration, HSTROBE high between consecutive accesses
Setup time, select signals§ valid before HAS low
*2P
ns
4
ns
Hold time, select signals§ valid after HAS low
2
ns
Setup time, host data valid before HSTROBE high
3
ns
Hold time, host data valid after HSTROBE high
2
ns
Hold time, HSTROBE low after HRDY low. HSTROBE should not be
inactivated until HRDY is active (low); otherwise, HPI writes will not
complete properly.
*1
ns
Setup time, HAS low before HSTROBE low
*2
ns
Hold time, HAS low after HSTROBE low
*2
ns
*This parameter is not tested.
† HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS.
‡ The effects of internal clock jitter are included at test. There is no need to adjust timing numbers for internal clock jitter. P = 1/CPU clock frequency
in ns. For example, when running parts at 167 MHz, use P = 6 ns.
§ Select signals include: HCNTRL[1:0], HR/W, and HHWIL.
switching characteristics during host-port interface cycles†‡ (see Figure 27, Figure 28, Figure 29,
and Figure 30)
NO.
PARAMETER
’C6701-14
’C6701-16
MIN
5
6
7
8
9
15
16
17
td(HCS-HRDY)
td(HSTBL-HRDYH)
Delay time, HCS to HRDY¶
toh(HSTBL-HDLZ)
td(HDV-HRDYL)
Output hold time, HD low impedance after HSTROBE low for an HPI read
toh(HSTBH-HDV)
td(HSTBH-HDHZ)
Output hold time, HD valid after HSTROBE high
td(HSTBL-HDV)
td(HSTBH-HRDYH)
Delay time, HSTROBE low to HRDY high#
Delay time, HD valid to HRDY low
UNIT
MAX
1
12
ns
1
12
ns
*4
ns
*P – 3 *P + 3
ns
3
12
ns
*3
*12
ns
Delay time, HSTROBE low to HD valid
3
12
ns
Delay time, HSTROBE high to HRDY high||
1
12
ns
Delay time, HSTROBE high to HD high impedance
*This parameter is not tested.
† HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS.
‡ The effects of internal clock jitter are included at test. There is no need to adjust timing numbers for internal clock jitter. P = 1/CPU clock frequency
in ns. For example, when running parts at 167 MHz, use P = 6 ns.
¶ HCS enables HRDY, and HRDY is always low when HCS is high. The case where HRDY goes high when HCS falls indicates that HPI is busy
completing a previous HPID write or READ with autoincrement.
# This parameter is used during an HPID read. At the beginning of the first half-word transfer on the falling edge of HSTROBE, the HPI sends the
request to the DMA auxiliary channel, and HRDY remains high until the DMA auxiliary channel loads the requested data into HPID.
|| This parameter is used after the second half-word of an HPID write or autoincrement read. HRDY remains low if the access is not an HPID write
or autoincrement read. Reading or writing to HPIC or HPIA does not affect the HRDY signal.
46
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
SGUS030B – APRIL 2000 – REVISED MAY 2001
HOST-PORT INTERFACE TIMING (CONTINUED)
HAS
1
1
2
2
HCNTL[1:0]
1
1
2
2
HR/W
1
1
2
2
HHWIL
4
3
HSTROBE†
HCS
15
9
7
15
9
16
HD[15:0] (output)
1st half-word
5
2nd half-word
8
17
5
HRDY (case 1)
6
8
17
5
HRDY (case 2)
† HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS.
Figure 27. HPI Read Timing (HAS Not Used, Tied High)
HAS
19
11
19
10
11
10
HCNTL[1:0]
11
11
10
10
HR/W
11
11
10
10
HHWIL
4
3
HSTROBE†
18
18
HCS
15
7
9
15
16
9
HD[15:0] (output)
1st half-word
5
8
2nd half-word
17
5
17
5
HRDY (case 1)
6
8
HRDY (case 2)
† HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS.
Figure 28. HPI Read Timing (HAS Used)
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
47
SGUS030B – APRIL 2000 – REVISED MAY 2001
HOST-PORT INTERFACE TIMING (CONTINUED)
HAS
1
1
2
2
HCNTL[1:0]
12
12
13
13
HBE[1:0]
1
1
2
2
HR/W
1
1
2
2
HHWIL
3
4
14
HSTROBE†
HCS
12
12
13
13
HD[15:0] (input)
1st half-word
5
17
2nd half-word
5
HRDY
† HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS.
Figure 29. HPI Write Timing (HAS Not Used, Tied High)
HAS
12
19
13
12
19
13
HBE[1:0]
11
11
10
10
HCNTL[1:0]
11
11
10
10
HR/W
11
11
10
10
HHWIL
3
14
HSTROBE†
4
18
18
HCS
12
13
12
13
HD[15:0] (input)
5
1st half-word
2nd half-word
17
HRDY
† HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS.
Figure 30. HPI Write Timing (HAS Used)
48
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
5
SGUS030B – APRIL 2000 – REVISED MAY 2001
MULTICHANNEL BUFFERED SERIAL PORT TIMING
timing requirements for McBSP†‡ (see Figure 31)
’C6701-14
’C6701-16
NO.
MIN
2
3
tc(CKRX)
tw(CKRX)
UNIT
MAX
Cycle time, CLKR/X
CLKR/X ext
*2P
ns
Pulse duration, CLKR/X high or CLKR/X low
CLKR/X ext
*P – 1
ns
5
tsu(FRH-CKRL)
Set p time,
Setup
time external
e ternal FSR high before CLKR low
lo
6
th(CKRL-FRH)
Hold time,
time external
e ternal FSR high after CLKR low
lo
7
tsu(DRV-CKRL)
Set p time
Setup
time, DR valid
alid before CLKR lo
low
8
th(CKRL-DRV)
time DR valid after CLKR low
Hold time,
10
tsu(FXH-CKXL)
Set p time,
Setup
time external
e ternal FSX high before CLKX low
lo
11
th(CKXL-FXH)
Hold time,
time external
e ternal FSX high after CLKX low
lo
CLKR int
*13
CLKR ext
4
CLKR int
*7
CLKR ext
4
CLKR int
10
CLKR ext
1
CLKR int
4
CLKR ext
4
CLKX int
*13
CLKX ext
4
CLKX int
*7
CLKX ext
3
ns
ns
ns
ns
ns
ns
† P = 1/CPU clock frequency in ns. For example, when running parts at 167 MHz, use P = 6 ns.
‡ CLKRP = CLKXP = FSRP = FSXP = 0 in the pin control register (PCR). If polarity of any of the signals is inverted, then the timing references
of that signal are also inverted.
*This parameter is not tested.
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
49
SGUS030B – APRIL 2000 – REVISED MAY 2001
MULTICHANNEL BUFFERED SERIAL PORT TIMING (CONTINUED)
switching characteristics for McBSP†‡§ (see Figure 31)
NO.
’C6701-14
’C6701-16
PARAMETER
Delay time, CLKS high to CLKR/X high for internal
CLKR/X generated from CLKS input
UNIT
MIN
MAX
3
15
1
td(CKSH-CKRXH)
2
tc(CKRX)
tw(CKRX)
Cycle time, CLKR/X
CLKR/X int
2P
3
Pulse duration, CLKR/X high or CLKR/X low
CLKR/X int
C – 1¶
C + 1¶
ns
4
td(CKRH-FRV)
Delay time, CLKR high to internal FSR valid
CLKR int
–4
4
ns
CLKX int
–4
5
CLKX ext
*3
*16
CLKX int
*–3
*2
CLKX ext
*2
*9
CLKX int
–2
4
CLKX ext
3
16
9
td(CKXH-FXV)
Dela time,
Delay
time CLKX high to internal FSX valid
alid
12
tdis(CKXH-DXHZ)
Disable time, DX high impedance
im edance following last data bit from
CLKX high
13
td(CKXH-DXV)
time CLKX high to DX valid.
valid
Delay time,
14
td(FXH-DXV)
Delay time, FSX high to DX valid.
ONLY applies when in data delay 0 (XDATDLY = 00b) mode.
ns
ns
FSX int
*–2
*4
FSX ext
*2
*10
ns
ns
ns
ns
† CLKRP = CLKXP = FSRP = FSXP = 0 in the pin control register (PCR). If polarity of any of the signals is inverted, then the timing references
of that signal are also inverted.
‡ Minimum delay times also represent minimum output hold times.
§ P = 1/CPU clock frequency in ns. For example, when running parts at 167 MHz, use P = 6 ns.
¶ C = H or L
S = sample rate generator input clock = P if CLKSM = 1 (P = 1/CPU clock frequency)
= sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period)
H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even
= (CLKGDV + 1)/2 * S if CLKGDV is odd or zero
L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even
= (CLKGDV + 1)/2 * S if CLKGDV is odd or zero
*This parameter is not tested.
50
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
SGUS030B – APRIL 2000 – REVISED MAY 2001
MULTICHANNEL BUFFERED SERIAL PORT TIMING (CONTINUED)
CLKS
1
2
3
3
CLKR
4
4
FSR (int)
5
6
FSR (ext)
7
DR
8
Bit(n-1)
(n-2)
(n-3)
2
3
3
CLKX
9
FSX (int)
11
10
FSX (ext)
FSX (XDATDLY=00b)
12
DX
Bit 0
14
13
Bit(n-1)
13
(n-2)
(n-3)
Figure 31. McBSP Timings
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
51
SGUS030B – APRIL 2000 – REVISED MAY 2001
MULTICHANNEL BUFFERED SERIAL PORT TIMING (CONTINUED)
timing requirements for FSR when GSYNC = 1 (see Figure 32)
’C6701-14
’C6701-16
NO.
MIN
1
2
tsu(FRH-CKSH)
th(CKSH-FRH)
Setup time, FSR high before CLKS high
*4
ns
Hold time, FSR high after CLKS high
*4
ns
*This parameter is not tested.
CLKS
1
2
FSR external
CLKR/X (no need to resync)
CLKR/X(needs resync)
Figure 32. FSR Timing When GSYNC = 1
52
UNIT
MAX
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
SGUS030B – APRIL 2000 – REVISED MAY 2001
MULTICHANNEL BUFFERED SERIAL PORT TIMING (CONTINUED)
timing requirements for McBSP as SPI master or slave: CLKSTP = 10b, CLKXP = 0†‡ (see Figure 33)
’C6701-14
’C6701-16
NO
NO.
MASTER
MIN
4
tsu(DRV-CKXL)
th(CKXL-DRV)
Setup time, DR valid before CLKX low
UNIT
SLAVE
MAX
12
MIN
MAX
2 – 3P
ns
5
Hold time, DR valid after CLKX low
4
5 + 6P
ns
† The effects of internal clock jitter are included at test. There is no need to adjust timing numbers for internal clock jitter. P = 1/CPU clock frequency
in ns. For example, when running parts at 167 MHz, use P = 6 ns.
‡ For all SPI slave modes, CLKG is programmed as 1/2 of the CPU clock by setting CLKSM = CLKGDV = 1.
switching characteristics for McBSP as SPI master or slave: CLKSTP = 10b, CLKXP = 0†‡
(see Figure 33)
’C6701-14
’C6701-16
NO
NO.
PARAMETER
MASTER§
2
th(CKXL-FXL)
td(FXL-CKXH)
Hold time, FSX low after CLKX low¶
Delay time, FSX low to CLKX high#
3
td(CKXH-DXV)
Delay time, CLKX high to DX valid
6
tdis(CKXL-DXHZ)
Disable time, DX high impedance following last data bit from
CLKX low
7
tdis(FXH-DXHZ)
Disable time, DX high impedance following last data bit from
FSX high
1
UNIT
SLAVE
MIN
MAX
T–4
T+4
L–4
L+4
–4
4
*L – 2
*L + 3
MIN
MAX
ns
ns
3P + 1
5P + 17
ns
ns
*P + 4
*3P + 17
ns
8
td(FXL-DXV)
Delay time, FSX low to DX valid
2P + 1
4P + 13
ns
*This parameter is not tested.
† The effects of internal clock jitter are included at test. There is no need to adjust timing numbers for internal clock jitter. P = 1/CPU clock frequency
in ns. For example, when running parts at 167 MHz, use P = 6 ns.
‡ For all SPI slave modes, CLKG is programmed as 1/2 of the CPU clock by setting CLKSM = CLKGDV = 1.
§ S = sample rate generator input clock = P if CLKSM = 1 (P = 1/CPU clock frequency)
= sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period)
T = CLKX period = (1 + CLKGDV) * S
H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even
= (CLKGDV + 1)/2 * S if CLKGDV is odd or zero
L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even
= (CLKGDV + 1)/2 * S if CLKGDV is odd or zero
¶ FSRP = FSXP = 1. As a SPI master, FSX is inverted to provide active-low slave-enable output. As a slave, the active-low signal input on FSX
and FSR is inverted before being used internally.
CLKXM = FSXM = 1, CLKRM = FSRM = 0 for master McBSP
CLKXM = CLKRM = FSXM = FSRM = 0 for slave McBSP
# FSX should be low before the rising edge of clock to enable slave devices and then begin a SPI transfer at the rising edge of the master clock
(CLKX).
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
53
SGUS030B – APRIL 2000 – REVISED MAY 2001
MULTICHANNEL BUFFERED SERIAL PORT TIMING (CONTINUED)
CLKX
1
2
FSX
7
6
DX
8
3
Bit 0
Bit(n-1)
4
DR
Bit 0
(n-2)
(n-3)
(n-4)
5
Bit(n-1)
(n-2)
(n-3)
(n-4)
Figure 33. McBSP Timing as SPI Master or Slave: CLKSTP = 10b, CLKXP = 0
timing requirements for McBSP as SPI master or slave: CLKSTP = 11b, CLKXP = 0†‡ (see Figure 34)
’C6701-14
’C6701-16
NO
NO.
MASTER
MIN
4
5
tsu(DRV-CKXH)
th(CKXH-DRV)
Setup time, DR valid before CLKX high
MIN
12
2 – 3P
4
5 + 6P
MAX
ns
ns
† The effects of internal clock jitter are included at test. There is no need to adjust timing numbers for internal clock jitter. P = 1/CPU clock frequency
in ns. For example, when running parts at 167 MHz, use P = 6 ns.
‡ For all SPI slave modes, CLKG is programmed as 1/2 of the CPU clock by setting CLKSM = CLKGDV = 1.
54
Hold time, DR valid after CLKX high
MAX
UNIT
SLAVE
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
SGUS030B – APRIL 2000 – REVISED MAY 2001
MULTICHANNEL BUFFERED SERIAL PORT TIMING (CONTINUED)
switching characteristics for McBSP as SPI master or slave: CLKSTP = 11b, CLKXP = 0†‡
(see Figure 34)
’C6701-14
’C6701-16
NO
NO.
PARAMETER
MASTER§
2
th(CKXL-FXL)
td(FXL-CKXH)
Hold time, FSX low after CLKX low¶
Delay time, FSX low to CLKX high#
3
td(CKXL-DXV)
Delay time, CLKX low to DX valid
tdis(CKXL-DXHZ)
Disable time, DX high impedance following last data bit
from CLKX low
1
6
UNIT
SLAVE
MIN
MAX
L–4
L+4
MIN
MAX
ns
T–4
T+4
ns
–4
4
3P + 1
5P + 17
ns
*–2
*4
*3P + 4
*5P + 17
ns
7
td(FXL-DXV)
Delay time, FSX low to DX valid
*H – 2
*H + 3
2P + 1
4P + 13
ns
*This parameter is not tested.
† The effects of internal clock jitter are included at test. There is no need to adjust timing numbers for internal clock jitter. P = 1/CPU clock frequency
in ns. For example, when running parts at 167 MHz, use P = 6 ns.
‡ For all SPI slave modes, CLKG is programmed as 1/2 of the CPU clock by setting CLKSM = CLKGDV = 1.
§ S = sample rate generator input clock = P if CLKSM = 1 (P = 1/CPU clock frequency)
= sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period)
T = CLKX period = (1 + CLKGDV) * S
H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even
= (CLKGDV + 1)/2 * S if CLKGDV is odd or zero
L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even
= (CLKGDV + 1)/2 * S if CLKGDV is odd or zero
¶ FSRP = FSXP = 1. As a SPI master, FSX is inverted to provide active-low slave-enable output. As a slave, the active-low signal input on FSX
and FSR is inverted before being used internally.
CLKXM = FSXM = 1, CLKRM = FSRM = 0 for master McBSP
CLKXM = CLKRM = FSXM = FSRM = 0 for slave McBSP
# FSX should be low before the rising edge of clock to enable slave devices and then begin a SPI transfer at the rising edge of the master clock
(CLKX).
CLKX
1
2
6
Bit 0
7
FSX
DX
3
Bit(n-1)
4
DR
Bit 0
(n-2)
(n-3)
(n-4)
5
Bit(n-1)
(n-2)
(n-3)
(n-4)
Figure 34. McBSP Timing as SPI Master or Slave: CLKSTP = 11b, CLKXP = 0
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
55
SGUS030B – APRIL 2000 – REVISED MAY 2001
MULTICHANNEL BUFFERED SERIAL PORT TIMING (CONTINUED)
timing requirements for McBSP as SPI master or slave: CLKSTP = 10b, CLKXP = 1†‡ (see Figure 35)
’C6701-14
’C6701-16
NO
NO.
MASTER
MIN
4
tsu(DRV-CKXH)
th(CKXH-DRV)
Setup time, DR valid before CLKX high
UNIT
SLAVE
MAX
12
MIN
MAX
2 – 3P
ns
5
Hold time, DR valid after CLKX high
4
5 + 6P
ns
† The effects of internal clock jitter are included at test. There is no need to adjust timing numbers for internal clock jitter. P = 1/CPU clock frequency
in ns. For example, when running parts at 167 MHz, use P = 6 ns.
‡ For all SPI slave modes, CLKG is programmed as 1/2 of the CPU clock by setting CLKSM = CLKGDV = 1.
switching characteristics for McBSP as SPI master or slave: CLKSTP = 10b, CLKXP = 1†‡
(see Figure 35)
’C6701-14
’C6701-16
NO
NO.
PARAMETER
MASTER§
MIN
2
th(CKXH-FXL)
td(FXL-CKXL)
Hold time, FSX low after CLKX high¶
Delay time, FSX low to CLKX low#
3
td(CKXL-DXV)
Delay time, CLKX low to DX valid
6
tdis(CKXH-DXHZ)
Disable time, DX high impedance following last data bit
from CLKX high
7
tdis(FXH-DXHZ)
Disable time, DX high impedance following last data bit
from FSX high
1
MAX
T–4
T+4
H–4
H+4
–4
4
*H – 2
*H + 3
8
UNIT
SLAVE
MIN
MAX
ns
ns
3P + 1
5P + 17
ns
ns
*P + 4
*3P + 17
ns
td(FXL-DXV)
Delay time, FSX low to DX valid
2P + 1
4P + 13
ns
*This parameter is not tested.
† The effects of internal clock jitter are included at test. There is no need to adjust timing numbers for internal clock jitter. P = 1/CPU clock frequency
in ns. For example, when running parts at 167 MHz, use P = 6 ns.
‡ For all SPI slave modes, CLKG is programmed as 1/2 of the CPU clock by setting CLKSM = CLKGDV = 1.
§ S = sample rate generator input clock = P if CLKSM = 1 (P = 1/CPU clock frequency)
= sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period)
T = CLKX period = (1 + CLKGDV) * S
H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even
= (CLKGDV + 1)/2 * S if CLKGDV is odd or zero
L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even
= (CLKGDV + 1)/2 * S if CLKGDV is odd or zero
¶ FSRP = FSXP = 1. As a SPI master, FSX is inverted to provide active-low slave-enable output. As a slave, the active-low signal input on FSX
and FSR is inverted before being used internally.
CLKXM = FSXM = 1, CLKRM = FSRM = 0 for master McBSP
CLKXM = CLKRM = FSXM = FSRM = 0 for slave McBSP
# FSX should be low before the rising edge of clock to enable slave devices and then begin a SPI transfer at the rising edge of the master clock
(CLKX).
56
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
SGUS030B – APRIL 2000 – REVISED MAY 2001
MULTICHANNEL BUFFERED SERIAL PORT TIMING (CONTINUED)
CLKX
1
2
FSX
7
6
DX
8
3
Bit 0
Bit(n-1)
4
DR
Bit 0
(n-2)
(n-3)
(n-4)
5
Bit(n-1)
(n-2)
(n-3)
(n-4)
Figure 35. McBSP Timing as SPI Master or Slave: CLKSTP = 10b, CLKXP = 1
timing requirements for McBSP as SPI master or slave: CLKSTP = 11b, CLKXP = 1†‡ (see Figure 36)
’C6701-14
’C6701-16
NO
NO.
MASTER
MIN
4
5
tsu(DRV-CKXL)
th(CKXL-DRV)
Setup time, DR valid before CLKX low
Hold time, DR valid after CLKX low
MAX
UNIT
SLAVE
MIN
12
2 – 3P
4
5 + 6P
MAX
ns
ns
† The effects of internal clock jitter are included at test. There is no need to adjust timing numbers for internal clock jitter. P = 1/CPU clock frequency
in ns. For example, when running parts at 167 MHz, use P = 6 ns.
‡ For all SPI slave modes, CLKG is programmed as 1/2 of the CPU clock by setting CLKSM = CLKGDV = 1.
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
57
SGUS030B – APRIL 2000 – REVISED MAY 2001
MULTICHANNEL BUFFERED SERIAL PORT TIMING (CONTINUED)
switching characteristics for McBSP as SPI master or slave: CLKSTP = 11b, CLKXP = 1†‡
(see Figure 36)
’C6701-14
’C6701-16
NO
NO.
PARAMETER
MASTER§
2
th(CKXH-FXL)
td(FXL-CKXL)
Hold time, FSX low after CLKX high¶
Delay time, FSX low to CLKX low#
3
td(CKXH-DXV)
Delay time, CLKX high to DX valid
tdis(CKXH-DXHZ)
Disable time, DX high impedance following last data bit from
CLKX high
1
6
UNIT
SLAVE
MIN
MAX
H–4
H+4
MIN
MAX
ns
T–4
T+4
ns
–4
4
3P + 1
5P + 17
ns
*–2
*4
*3P + 4
*5P + 17
ns
7
td(FXL-DXV)
Delay time, FSX low to DX valid
*L – 2 *L + 3
2P + 1
4P + 13
ns
*This parameter is not tested.
† The effects of internal clock jitter are included at test. There is no need to adjust timing numbers for internal clock jitter. P = 1/CPU clock frequency
in ns. For example, when running parts at 167 MHz, use P = 6 ns.
‡ For all SPI slave modes, CLKG is programmed as 1/2 of the CPU clock by setting CLKSM = CLKGDV = 1.
§ S = sample rate generator input clock = P if CLKSM = 1 (P = 1/CPU clock frequency)
= sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period)
T = CLKX period = (1 + CLKGDV) * S
H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even
= (CLKGDV + 1)/2 * S if CLKGDV is odd or zero
L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even
= (CLKGDV + 1)/2 * S if CLKGDV is odd or zero
¶ FSRP = FSXP = 1. As a SPI master, FSX is inverted to provide active-low slave-enable output. As a slave, the active-low signal input on FSX
and FSR is inverted before being used internally.
CLKXM = FSXM = 1, CLKRM = FSRM = 0 for master McBSP
CLKXM = CLKRM = FSXM = FSRM = 0 for slave McBSP
# FSX should be low before the rising edge of clock to enable slave devices and then begin a SPI transfer at the rising edge of the master clock
(CLKX).
CLKX
1
2
FSX
7
6
DX
3
Bit 0
Bit(n-1)
4
DR
Bit 0
(n-2)
(n-3)
(n-4)
5
Bit(n-1)
(n-2)
(n-3)
(n-4)
Figure 36. McBSP Timing as SPI Master or Slave: CLKSTP = 11b, CLKXP = 1
58
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
SGUS030B – APRIL 2000 – REVISED MAY 2001
DMAC, TIMER, POWER-DOWN TIMING
switching characteristics for DMAC outputs (see Figure 37)
NO.
1
’C6701-14
’C6701-16
PARAMETER
td(CKO1H-DMACV)
UNIT
MIN
MAX
2
11
Delay time, CLKOUT1 high to DMAC valid
ns
CLKOUT1
1
1
DMAC[0:3]
Figure 37. DMAC Timing
timing requirements for timer inputs (see Figure 38)†
’C6701-14
’C6701-16
NO.
MIN
1
tw(TINPH)
Pulse duration, TINP high
† P = 1/CPU clock frequency in ns. For example, when running parts at 167 MHz, use P = 6 ns.
UNIT
MAX
2P
ns
switching characteristics for timer outputs (see Figure 38)
NO.
2
’C6701-14
’C6701-16
PARAMETER
td(CKO1H-TOUTV)
Delay time, CLKOUT1 high to TOUT valid
UNIT
MIN
MAX
1
10
ns
CLKOUT1
1
TINP
2
2
TOUT
Figure 38. Timer Timing
switching characteristics for power-down outputs (see Figure 39)
NO.
1
’C6701-14
’C6701-16
PARAMETER
td(CKO1H-PDV)
Delay time, CLKOUT1 high to PD valid
UNIT
MIN
MAX
1
9
ns
CLKOUT1
1
1
PD
Figure 39. Power-Down Timing
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
59
SGUS030B – APRIL 2000 – REVISED MAY 2001
JTAG TEST-PORT TIMING
timing requirements for JTAG test port (see Figure 40)
’C6701-14
’C6701-16
NO.
MIN
1
UNIT
MAX
tc(TCK)
tsu(TDIV-TCKH)
Cycle time, TCK
35
ns
3
Setup time, TDI/TMS/TRST valid before TCK high
10
ns
4
th(TCKH-TDIV)
Hold time, TDI/TMS/TRST valid after TCK high
9
ns
switching characteristics for JTAG test port (see Figure 40)
NO.
’C6701-14
’C6701-16
PARAMETER
2
td(TCKL-TDOV) Delay time, TCK low to TDO valid
*This parameter is not tested.
MIN
MAX
*–3
*15
1
TCK
2
2
TDO
4
3
TDI/TMS/TRST
Figure 40. JTAG Test-Port Timing
60
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
UNIT
ns
SGUS030B – APRIL 2000 – REVISED MAY 2001
MECHANICAL DATA
GLP (S-CBGA-N429)
CERAMIC BALL GRID ARRAY
27,20
SQ
26,80
25,40 TYP
1,27
AA
Y
W
V
U
T
R
P
N
M
L
K
J
H
G
F
E
D
C
B
A
1,27
1
3
2
1,22
1,00
5
4
9
7
6
8
10
11 13 15 17 19 21
12 14 16 18 20
3,30 MAX
Seating Plane
0,90
0,60
NOTES: A.
B.
C.
D.
∅ 0,10 M
0,70
0,50
0,15
4164732/A 08/98
All linear dimensions are in millimeters.
This drawing is subject to change without notice.
Falls within JEDEC MO-156
Flip chip application only
thermal resistance characteristics (S-CBGA package)
°C/W
Air Flow
3.0
N/A
Junction-to-Case, measured to the top of the package lid
7.3
N/A
Junction-to-Ambient
14.5
0
11.8
150 fpm
11.1
250 fpm
10.2
500 fpm
6.2
N/A
NO
1
Junction-to-Case, measured to the bottom of solder ball
2
RΘJC
RΘJC
3
RΘJA
RΘJMA
Junction-to-Moving-Air
Junction
to Moving Air
4
5
6
7
RΘJB
Junction-to-Board, measured by soldering a thermocouple to one of the middle
traces on the board at the edge of the package
POST OFFICE BOX 1443
• HOUSTON, TEXAS 77251–1443
61
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
5962-9866101QXA
ACTIVE
FC/CSP
GLP
429
1
None
Call TI
Level-NC-NC-NC
5962-9866101VXA
ACTIVE
FC/CSP
GLP
429
1
None
Call TI
Level-NC-NC-NC
Lead/Ball Finish
MSL Peak Temp (3)
5962-9866102VXA
ACTIVE
FC/CSP
GLP
429
1
None
Call TI
Level-NC-NC-NC
SM320C6701GLPS16
ACTIVE
FC/CSP
GLP
429
1
None
Call TI
Level-NC-NC-NC
SM320C6701GLPW14
ACTIVE
FC/CSP
GLP
429
1
None
Call TI
Level-NC-NC-NC
SMJ320C6701GLPW14
ACTIVE
FC/CSP
GLP
429
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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