LSI L9A0212 Microprocessor Datasheet

TinyRISC® LR4102
Microprocessor
Datasheet
The TinyRISC LR4102 Microprocessor is a compact, high performance
32-bit microprocessor implemented in the LSI Logic G11™ technology.
The LR4102 is a complete microprocessor solution with caches, an
external bus interface with built-in memory controllers, and on-chip
debug. The LR4102 is built using the EZ4102 EasyMACRO subsystem,
available to customers through the LSI Logic CoreWare® program.
The LR4102 provides a 32-bit FBusMACRO to control all off-chip data
transactions (including DRAM or SDRAM) and an EJTAG interface for
on-chip debug with PC trace output. Figure 1 illustrates the LR4102 chip.
Figure 1
LR4102 Block Diagram
LR4102
MMU
TLB RAM
Caches
Clock
Controller
32-bit TinyRISC
4102 CPU
and FastMDU
BIU and Cache
Controller (BBCC)
OCM
FBusMACRO
FBus
Two 32-bit Timers
SerialICE™-1 Port
EJTAG
EJTAG
Extended Debug MACRO
SerialICE-1
Interface
EJTAG
Interface
PC Trace
Output
The LR4102 microprocessor is powered by either 2.5 V (for 85 MHz
operation) or 1.8 V (for 50 MHz operation). The chip I/O ring requires
3.3 V. With a system clock of 85 MHz, peak performance is 85 MIPS and
sustained performance is estimated at 68 MIPS. With a 50 MHz clock,
performance is 50 MIPS peak and 40 MIPS sustained.
March 2000
Copyright © 1998–2000 by LSI Logic Corporation. All rights reserved.
1
LR4102 Features
Components
•
•
R3000 MIPS CPU executes
MIPS II and MIPS16
instructions
32-bit FBus, a fast
demultiplexed multimaster
bus, with built in control of:
–
RAM, EPROM, or similar
simple devices
–
–
DRAM and SDRAM
General-purpose I/O
•
Two 32-bit Timers
•
FastMDU
–
4/5 cycle multiply and
accumulate (32-bit to
64-bit)
•
Caches
–
16 Kbytes of two-way
set-associative I-Cache
–
8 Kbytes of direct-mapped
D-Cache
Clock module with integrated
PLL and programmable clock
speeds
Technology
•
LSI Logic G11 Technology
–
–
0.18 µ Leff (0.25 µ drawn)
2.5 or 1.8 V operation
Performance and Compatibility
•
Clock speed is 85 MHz at 2.5 V
(85 MIPS peak and estimated
68 MIPS sustained)
•
Low power mode allows LR4102
to use minimal power when idle
•
MMU with 64-entry TLB RAM •
•
EJTAG Version 2.0.0:
Compatible with the full range of
MIPS and third-party software
development tools
•
•
2
•
– 34/35 cycle divide
BBCC with four writeback
buffers included
– Nonintrusive debug
•
– Real-time PC trace
– Hardware breakpoints
SerialICE-1 Port included for •
backward compatibility with
other TinyRISC designs
•
JTAG Boundary Scan
•
On-Chip Memory (OCM),
1 Kbyte
TinyRISC LR4102 Microprocessor
16-bit and 32-bit code can be
mixed arbitrarily with full support
on a subroutine basis
All instructions execute in one
cycle except for Load and Store,
Move To Coprocessor, and Move
From Coprocessor, which
execute in two cycles, and MDU
instructions, which execute in
several cycles
Block Diagram
This section provides short descriptions of the major components of the
LR4102, as shown in Figure 1.
The CPU performs all arithmetic, logical, shift, and address calculations.
The CPU supports EJTAG debug and is closely coupled with the
FastMDU. The FastMDU calculates all multiply and divide operations for
the LR4102, and provides 4/5 cycle multiply and accumulate operations
(32 bit to 64 bit), 34/35 cycle divide, saturated math, and overflow
indication.
The memory management unit (MMU) translates virtual addresses from
the CPU into physical addresses and includes a 64-entry translation
look-aside buffer (TLB) RAM.
The BIU and cache controller (BBCC) provides an internal bus interface
and connects the CPU to the caches. For the caches, the LR4102
contains 16 Kbytes of two-way set-associative I-Cache and 8 Kbytes of
direct-mapped D-Cache. Four Write Buffers are integrated with the
BBCC in the LR4102 design.
The 32-bit FBusMACRO (FBM) controls the FBus, a dedicated,
multimaster bus that connects off-chip logic with the LR4102. The FBus
allows seamless LR4102 connection to a variety of devices, including
EPROM, FLASH, RAM, DRAM, SDRAM, and general-purpose I/O pins.
The FBus also supports burst read (one cycle) and write, built-in
arbitration for an external FBus master, and snooping of external write
accesses to memory. Internally, the FBusMACRO interfaces mainly with
the BBCC module.
Each 32-bit Timer can count down from a preloaded value, roll over or
stop at zero, generate an interrupt on zero, or act as bus watchdog. The
CPU can program either of the two internal 32-bit timers.
The LR4102 includes 1 Kbyte of on-chip memory (OCM).
The Clock Controller steps CPU clock speed up or down, and can stop
the internal LR4102 clock altogether. The LR4102 also supports a low
power mode. The LR4102 Clock Controller is designed to support a
crystal or canned oscillator, and has an on-chip PLL for frequency
multiplication.
TinyRISC LR4102 Microprocessor
3
The EJTAG with PC Trace output provides real-time program counter
(PC) trace and breakpoint capability in an EJTAG compatible debug
design. PC trace outputs are provided through the Extended Debug
MACRO for complete and accurate chip debug. A SerialICE-1 Port
(UART) is also included in the LR4102 to provide backward compatibility
with previous TinyRISC designs.
Pipeline Architecture
The LR4102 implements a 3-stage pipeline (Fetch, Execute, and
Writeback) that uses a single adder for the ALU, the data address, and
the instruction address. Sharing a single adder dramatically reduces the
circuitry required to implement the microprocessor, and eliminates
pipeline registers and bypass logic. The LR4102 design does not require
a load delay slot. Figure 2 shows the microprocessor CPU 3-stage
pipeline.
Figure 2
LR4102 CPU Pipeline with X2 Stall Cycle
IF
X1
X2
WB
Stall
Instruction Fetch
Execute
Writeback
The execution of a single LR4102 instruction consists of the following
three pipeline stages:
1. Instruction Fetch – The LR4102 fetches the instruction (IF), and if
necessary, decompresses a 16-bit instruction into a 32-bit
instruction.
2. Execute – The LR4102 executes all ALU instructions, resolves
conditional branches, and calculates load and store addresses (X1).
The CPU then transfers load or store data from external memory or
cache and performs move to/from coprocessor operations in a second
execute (stall) cycle (X2), which is only inserted when required.
3. Writeback – The LR4102 writes the results into the register file (WB).
4
TinyRISC LR4102 Microprocessor
Instruction Set Summary
Table 1 summarizes the 32-bit instruction set for the LR4102, and Table
2 lists the unimplemented MIPS II instructions. Table 3 provides a
summary of the LR4102 MIPS16 instruction set.
Table 1
LR4102 32-Bit Instruction Set Summary
Load and Store Instructions
LB
Load Byte
SB
Store Byte
LBU
Load Byte Unsigned
SH
Store Halfword
LH
Load Halfword
SW
Store Word
LHU
Load Halfword Unsigned
SWL
Store Word Left
LW
Load Word
SWR
Store Word Right
LWL
Load Word Left
SYNC
Synchronize (load/store
synchronization)
LWR
Load Word Right
–
–
Arithmetic Instructions: ALU Immediate
ADDI
Add Immediate
ORI
OR Immediate
ADDIU
Add Immediate Unsigned
SLTI
Set on Less Than Immediate
ANDI
AND Immediate
SLTIU
Set on Less Than Immediate
Unsigned
LUI
Load Upper Immediate
XORI
Exclusive OR Immediate
Arithmetic Instructions: Three-Operand, Register-Type
ADD
Add
SLT
Set on Less Than
ADDU
Add Unsigned
SLTU
Set on Less Than Unsigned
AND
Logical AND
SUB
Subtract
NOR
Logical NOR
SUBU
Subtract Unsigned
OR
Logical OR
XOR
Logical Exclusive OR
(Sheet 1 of 4)
TinyRISC LR4102 Microprocessor
5
Table 1
LR4102 32-Bit Instruction Set Summary (Cont.)
Shift Instructions
SLL
Shift Left Logical
SRAV
Shift Right Arithmetic Variable
SLLV
Shift Left Logical Variable
SRL
Shift Right Logical
SRA
Shift Right Arithmetic
SRLV
Shift Right Logical Variable
Multiply/Divide Instructions
DIV
Divide
MSUBU1
Multiply Subtract Unsigned
DIVU
Divide Unsigned
MTHI
Move To HI
MADD1
Multiply Add
MTLO
Move To LO
MADDU1
Multiply Add Unsigned
MUL1
Three-Operand Multiply
MFHI
Move From HI
MULT
Multiply
MFLO
Move From LO
MULTU
Multiply Unsigned
MSUB1
Multiply Subtract
–
–
Jump and Branch Instructions
BCzF
Branch on Coprocessor z False
BLTZAL
Branch on Less Than Zero and
Link
BCzT
Branch on Coprocessor z True
BNE
Branch on Not Equal
BEQ
Branch on Equal
J
Jump
BGEZ
Branch on Greater Than or Equal to
Zero
JAL
Jump and Link
BGEZAL
Branch on Greater Than or Equal to
Zero and Link
JALR
Jump and Link Register
BGTZ
Branch on Greater Than Zero
JALX
Jump and Link Exchange
BLEZ
Branch on Less Than or Equal to Zero JR
Jump Register
BLTZ
Branch on Less Than Zero
BGTZL
Branch on Greater Than Zero
Likely
BCzFL
Branch on Coprocessor z False Likely
BLEZL
Branch on Less Than or Equal to
Zero Likely
(Sheet 2 of 4)
6
TinyRISC LR4102 Microprocessor
Table 1
LR4102 32-Bit Instruction Set Summary (Cont.)
Jump and Branch Instructions (Cont.)
BCzTL
Branch on Coprocessor z True Likely
BLTZALL
Branch on Less Than Zero and
Link Likely
BEQL
Branch on Equal Likely
BLTZL
Branch on Less Than Zero Likely
BGEZALL
Branch on Greater Than or Equal to
Zero and Link Likely
BNEL
Branch on Not Equal Likely
BGEZL
Branch on Greater Than or Equal to
Zero Likely
–
–
Coprocessor Instructions
BCzF
Branch on Coprocessor z False
MTCz
Move to Coprocessor z
BCzT
Branch on Coprocessor z True
MFCz
Move from Coprocessor z
COPz
Coprocessor Operation
SWCz
Store Word from Coprocessor z
(z ≠ 0)
CTCz
Move Control to Coprocessor z
BCzFL
Branch on Coprocessor z False
Likely
CFCz
Move Control from Coprocessor z
BCzTL
Branch on Coprocessor z True
Likely
LWCz
Load Word to Coprocessor z
(z ≠ 0)
–
–
System Control Coprocessor (CP0)
MFC0
Move from CP0
RFE
Restore from Exception
MTC0
Move to CP0
WAITI1
Wait for Interrupt
TLBR
Read Indexed TLB Entry
TLBWI
Write Indexed TLB Entry
TLBWR
Write Random TLB Entry
TLBP
Probe TLB for Matching Entry
SYSCALL
System Call
TLT
Trap if Less Than
Special Control Instructions
BREAK
Breakpoint
Trap Instructions
TEQ
Trap if Equal
(Sheet 3 of 4)
TinyRISC LR4102 Microprocessor
7
Table 1
LR4102 32-Bit Instruction Set Summary (Cont.)
Trap Instructions (Cont.)
TEQI
Trap if Equal Immediate
TLTI
Trap if Less Than Immediate
TGE
Trap if Greater Than or Equal
TLTIU
Trap if Less Than Immediate
Unsigned
TGEI
Trap if Greater Than or Equal
Immediate
TLTU
Trap if Less Than Unsigned
TGEIU
Trap if Greater Than or Equal
Immediate Unsigned
TNE
Trap if Not Equal
TGEU
Trap if Greater Than or Equal Unsigned TNEI
Trap If Not Equal Immediate
EJTAG Debug Instructions
SDBBP
Software Debug Breakpoint
DERET
Debug Exception Return
(Sheet 4 of 4)
1. LR4102/EZ4102-specific instruction.
Table 2
Unimplemented Instructions Summary
Unimplemented MIPS II Instructions
COP1
All floating-point instructions
ERET
Exception Return
LL
Load Linked Word
LDCz
Load Doubleword to Coprocessor
SC
Store Conditional Word
SDCz
Store Doubleword to Coprocessor
8
TinyRISC LR4102 Microprocessor
Table 3
LR4102 16-Bit Instruction Set Summary
Load and Store Instructions
LB1
Load Byte
LW1
Load Word
LBU1
Load Byte Unsigned
SB1
Store Byte
LH1
Load Halfword
SH1
Store Halfword
LHU1
Load Halfword Unsigned
SW1
Store Word
Arithmetic Instructions: ALU Immediate
LI1
Load Immediate
SLTIU1
Set on Less Than Immediate
Unsigned
ADDIU1
Add Immediate Unsigned
CMPI1
Compare Immediate
SLTI1
Set on Less Than Immediate
–
–
Arithmetic Instructions: Two/Three Operand, Register Type
ADDU
Add Unsigned
AND
Logical AND
SUBU
Subtract Unsigned
OR
Logical OR
SLT
Set on Less Than
XOR
Exclusive Logical OR
SLTU
Set on Less Than Unsigned
NOT
Logical NOT
CMP
Compare
MOVE
Move
NEG
Negate
–
–
Shift Instructions
SLL1
Shift Left Logical
SLLV
Shift Left Logical Variable
SRL1
Shift Right Logical
SRLV
Shift Right Logical Variable
SRA1
Shift Right Arithmetic
SRAV
Shift Right Arithmetic Variable
(Sheet 1 of 2)
TinyRISC LR4102 Microprocessor
9
Table 3
LR4102 16-Bit Instruction Set Summary (Cont.)
Multiply/Divide Instructions
MULT
Multiply
DIVU
Divide Unsigned
MULTU
Multiply Unsigned
MFHI
Move From HI
DIV
Divide
MFLO
Move From LO
Jump and Branch Instructions
JAL
Jump and Link
BNEZ1
Branch on Not Equal to Zero
JALX
Jump and Link Exchange
BTEQZ1
Branch on T Equal to Zero
JR
Jump Register
BTNEZ1
Branch on T Not Equal to Zero
JALR
Jump and Link Register
B1
Branch Unconditional
BEQZ1
Branch on Equal to Zero
–
–
BREAK
Breakpoint
–
–
Special Instructions
EXTEND
Extend
EJTAG Debug Instructions
SDBBP
Software Debug Breakpoint
(Sheet 2 of 2)
1. Extensible instruction; for details, please see the documentation on the MIPS16 Application Specific
Extension to the MIPS ISA, which is available from MIPS Technologies Incorporated.
10
TinyRISC LR4102 Microprocessor
LR4102 Register Map
Table 4 shows the LR4102 microprocessor register memory map.
Table 4
LR4102 Register Memory Map
Register Name
Physical Address
Description
System configuration registers in BBCC
SCR1
0x1FFF.0000
System Configuration Register 1
SCR2
0x1FFF.0004
System Configuration Register 2
SCR3
0x1FFF.0008
System Configuration Register 3
T0ICR
0x1FFF.0100
Timer 0 Initial Count Register
T0CCR
0x1FFF.0104
Timer 0 Current Count Register
T1ICR
0x1FFF.0108
Timer 1 Initial Count Register
T1CCR
0x1FFF.010C
Timer 1 Current Count Register
TMR
0x1FFF.0110
Mode Register
TISR
0x1FFF.0114
Interrupt Status Register
Timer registers
SerialICE-1 Port (UART) registers
RxStatus
0x1FFF.0200
Receive (Rx) Status Register (Reading)
RxSetup
0x1FFF.0200
Receive (Rx) Setup Register (Writing)
RxData
0x1FFF.0204
Receive (Rx) Data Register
TxStatus
0x1FFF.0208
Transmit (Tx) Status Register
TxData
0x1FFF.020C
Transmit (Tx) Data Register
Reserved registers
Reserved
0x1FFF.0300–.03FF
Reserved for LSI Logic use
FACFG0
0x1FFF.0400
Configuration for address range 0
FACFG1
0x1FFF.0404
Configuration for address range 1
FBus registers
(Sheet 1 of 2)
TinyRISC LR4102 Microprocessor
11
Table 4
LR4102 Register Memory Map (Cont.)
Register Name
Physical Address
Description
FBus registers (Cont.)
FACFG2
0x1FFF.0408
Configuration for address range 2
FACFG3
0x1FFF.040C
Configuration for address range 3
FACFG4
0x1FFF.0410
Configuration for address range 4
FACFG5
0x1FFF.0414
Configuration for address range 5
FBUSTA
0x1FFF.0418
Bus turnaround register for address range 0–5
FACMP0
0x1FFF.0440
Address compare register address range 0
FACMP1
0x1FFF.0444
Address compare register address range 1
FACMP2
0x1FFF.0448
Address compare register address range 2
FACMP3
0x1FFF.044C
Address compare register address range 3
FACMP4
0x1FFF.0450
Address compare register address range 4
FACMP5
0x1FFF.0454
Address compare register address range 5
FBUSCMP
0x1FFF.0470
Address compare register for FBus address range.
FBUSAC
0x1FFF.0474
Address compare register for FBus I/O, memory, and
configuration address range.
FBUSCFG
0x1FFF.0480
Configuration for FBus when accessing outside
programmable address range 0–5.
FSDRAM
0x1FFF.0490
Configuration for external EDO (S)DRAM
FDRAMT
0x1FFF.0494
Timing parameters for external EDO DRAM
FSDRAMT
0x1FFF.0498
Timing parameters for external SDRAM
FGPCFG
0x1FFF.04C0
Configuration for General-Purpose I/O
FGPOUTPUT
0x1FFF.04C4
Output value for General-Purpose Outputs
FGPINPUT
0x1FFF.04C8
Input value for General-Purpose Inputs
Reserved registers
Reserved
0x1FFF.0500–.06FF
Reserved for LSI Logic use
On Chip Memory (OCM), 1 Kbytes
OCM area
0x1FFF.8000–.83FF
On chip memory. Placed on CBus, 1 cycle access
(Sheet 2 of 2)
12
TinyRISC LR4102 Microprocessor
Signal Descriptions
The signals are described in alphabetical order by mnemonic. Each
signal definition contains the mnemonic and the full signal name.
Mnemonics for signals that are active LOW end in an “N”, and
mnemonics for signals that are active HIGH end in a “P.” In the
descriptions that follow, the verb assert means to drive active. The verb
deassert means to drive inactive.
The LR4102 signals are divided into the following groups:
•
Control Signals
•
Clocking Interface
•
Timer Interface
•
SerialICE-1 Interface
•
EJTAG Interface and JTAG boundary scan signals
•
PC Trace Output
•
FBus Interface
•
Test Interface
•
Power Lines
Table 5 lists all of the LR4102 signals, grouped by interface.
Table 5
LR4102 Signal List
Signal Group
Mnemonic Name
Functional Description
I/O
Control Signals
RESETN
Asynchronous system reset
Input
BIG_ENDIANP
Big/Little Endian select
Input
CWAITIP
Wait for interrupt (low power mode)
Output
INTP[5:0]
Condition/Interrupt
Input
DEBUGMP
Debug mode
Output
(Sheet 1 of 4)
TinyRISC LR4102 Microprocessor
13
Table 5
LR4102 Signal List (Cont.)
Signal Group
Mnemonic Name
Functional Description
I/O
Clocking
Interface
EXTAL
Input from crystal/Oscillator
Input
XTAL
Output to crystal
Output
PBCLKP
FAPI clock
Output
SDCLKP
SDRAM clock
Output
DIVC[1:0]
The divide value for DIV C upon reset
Input
DIVA[1:0]
The divide value for DIV A
Input
SELECT_PLLN
Control clock source MUX
Input
RESET_OUTN
Delayed reset signal for FAPI bus
Output
PLLENP
Enable PLL
Input
PLLENARSTP
Enable PLL auto reset
Input
T0_OUTN
Timer 0 output
Output
T1_OUTN
Timer 1 output
Output
ICECLKP
SerialICE-1 Port clock
Input
ICERXP
SerialICE-1 Port receive
Input
ICETXP
SerialICE-1 Port transmit
Output
TCK
EJTAG Interface clock
Input
TMS
EJTAG Interface mode select
Input
TDI_DINT
EJTAG Interface data in/Debug interrupt
Input
TDO_TPC
EJTAG Interface data out/PC out
Output
TRST
EJTAG Interface reset
Input
PC Trace Output DCLK
PC Trace clock output
Output
PCST1[2:0]
PC Trace status set 1 [2:0]
Output
TPC[4:2]
PC Trace PC out [4:2]
Output
Timer Interface
SerialICE-1
Interface
EJTAG Interface
and JTAG
boundary scan
signals
(Sheet 2 of 4)
14
TinyRISC LR4102 Microprocessor
Table 5
LR4102 Signal List (Cont.)
Signal Group
Mnemonic Name
Functional Description
I/O
FBus Interface
CBEN[3:0]
Command/byte enable
Bidirectional
DEVSELN
Device select
Bidirectional
FADDRP[28:0]
Demultiplexed address bus
Output
FADP[31:0]
Multiplexed address/Data bus
Bidirectional
FALEP
Address latch enable
Output
FRAMEN
Cycle frame indicating a bus transaction is
beginning
Bidirectional
GNTN
Grant the FBus
Output
GP[5:0]
General-purpose pins
Bidirectional
GPIO[3:0]
General-purpose I/O pins
Bidirectional
GPRDN
General-purpose read enable
Output
GPWEN[3:0]
General-purpose write byte enable
Output
IRDYN
Initiator ready
Bidirectional
REQN
Request FBus
Input
SD_CASN0_DMP0
DRAM CAS0 or SDRAM data mask 0
Output
SD_CASN1_DMP1
DRAM CAS1 or SDRAM data mask 1
Output
SD_CASN2_DMP2
DRAM CAS2 or SDRAM data mask 2
Output
SD_CASN3_DMP3
DRAM CAS3 or SDRAM data mask 3
Output
SD_OEN_CASN
DRAM output enable or SDRAM CAS
Output
SDONEP
Snooping done
Output
SD_RASN
SDRAM RAS
Output
SD_RASN0_CSN0
DRAM RAS bank 0 or SDRAM CAS0
Output
SD_RASN1_CSN1
DRAM RAS bank 1 or SDRAM CAS1
Output
SD_WEN_WEN
DRAM write enable or SDRAM write enable Output
STOPN
Stop transaction
Bidirectional
(Sheet 3 of 4)
TinyRISC LR4102 Microprocessor
15
Table 5
LR4102 Signal List (Cont.)
Signal Group
Mnemonic Name
Functional Description
I/O
FBus Interface
TRDYN
Target ready
Bidirectional
Test Interface
CSHTSTP
Cache test enable
Input
IDDTN
IDD test
Input
JTAGALSOP
JTAG controller present
Input
PMON_OUTP
Process monitor output
Output
SCAN_ENABLEP
Enable scan chain loading
Input
SCAN__INP
Input to the scan chain
Input
SCAN_MODEP
Enable scan testing
Input
SCAN_OUTP
Output from the scan chain
Output
SCAN_RAMWEP
RAM write enable
Input
SELECT_CKOUT1N
Select PLL test
Input
TN
3-state all LR4102 output and bidirectional
signals
Input
VDD, VDD2
VDD for CPU core and oscillator 2.5 V or
1.8 V
Power
VDD4
VDD for I/O 3.3 V
Power
PLLVDD1
VDD to PLL 2.5 V. Requires VDD CPU core
and oscillator at 2.5 V, since PLL must be
disabled for VDD CPU core and clock at
1.8 V
Power
VSS, VSS2, VSS4,
PLLVSS1
VSS for CPU core, clock, I/O and PLL
Power
Power Lines
(Sheet 4 of 4)
16
TinyRISC LR4102 Microprocessor
LR4102 Specifications
This section specifies the LR4102 electrical characteristics and includes
the following subsections:
•
“AC Timing”
•
“Electrical Requirements”
AC Timing
This section describes the AC timing characteristics of the LR4102
interface. Figures 3 and 4 show the EXTAL and TCK clocks. Figures 5
through 9 illustrate the input and output timing relationship with respect
to various clocks (PBCLKP, SDCLKP, and DCLKP). Tables 6 through 14
list the minimum and maximum input and output values for the LR4102
interface signals. Note that all output signals have a 65 pF load.
Figure 3
EXTAL Clock Timing
EXTAL
1
Figure 4
TCK Clock Timing
TCK
2
TinyRISC LR4102 Microprocessor
17
Figure 5
Input Timing with Respect to PBCLKP
PBCLKP
Input
Setup
Hold
Note: PBCLKP equals the system clock (PCLKP) when the DIV C value in the Clock
module is 0b01. DIV C = 0b01 is used to show timing for signals related to the system
clock. The setting of DIV C only affects PBCLKP and the timing for signals related to
the FAPI clock (PBCLKP).
Figure 6
Output Timing with Respect to PBCLKP
PBCLKP
Output
Min Output
Max Output
Figure 7
Input Timing with Respect to SDCLKP
SDCLKP
Input
Setup
18
TinyRISC LR4102 Microprocessor
Hold
Figure 8
Output Timing with Respect to SDCLKP
SDCLKP
Output
Min Output
Max Output
Figure 9
Output Timing with Respect to DCLK
DCLK
Output
Min Output
Max Output
Table 6
EXTAL Input Timing
Frequency
Parameter
Input
Signal
Clock
Period
Min
Max
Units
1
EXTAL
5.88 ns
–
170
MHz
Table 7
TCK Input Timing
Frequency
Parameter
Input
Signal
Clock
Period
Min
Max
Units
2
TCK
11.76 ns
–
85
MHz
TinyRISC LR4102 Microprocessor
19
Table 8
AC Input Timing with respect to rising edge of PBCLKP1
Input Signal
Setup
Hold
Units
CBEN[3:0]
7.2
1.4
ns
DEVSELN
4.7
2.2
ns
FADP[31:0]3
2.9
2.7
ns
FRAMEN
7.4
2.2
ns
GP[5:0]2
2.8
2.6
ns
GPIO[3:0]2
1.8
2.8
ns
IRDYN
7.5
1.9
ns
REQN
3.5
1.5
ns
STOPN
4.7
1.7
ns
TRDYN
4.6
2.0
ns
1. With 65 pF load
2. This signal is related to the system clock, but not to the FAPI bus (see
Figure 5 note).
3. This signal is related to both the system clock and the FAPI bus (see
Figure 5 note).
Table 9
AC Input Timing with respect to rising edge of SDCLKP1
Input Signal
Setup
Hold
Units
FADP[31:0]
2.0
3.4
ns
1. With 65 pF load.
Table 10
20
AC Input Timing with respect to rising edge of TCK
Input
Setup
Hold
Units
TDI_DINT
1.9
1.1
ns
TMS
1.6
0.7
ns
TinyRISC LR4102 Microprocessor
Table 11
AC Output Timing with respect to rising edge of
PBCLKP1
Output Signal1
Min
Max
Units
CBEN[3:0]
1.0
8.0
ns
CWAITIP2
2.8
8.8
ns
DEBUGMP
3.1
9.3
ns
DEVSELN
0.8
7.2
ns
FADDRP[28:0]2
1.3
6.2
ns
FADP[31:0]3
0.8
7.4
ns
FALEP
1.6
6.1
ns
FRAMEN
1.0
7.5
ns
GNTN
2.3
7.0
ns
GP[5:0]2
0.4
7.0
ns
GPIO[3:0]2
0.3
6.8
ns
GPRDN2
1.7
5.8
ns
GPWEN[3:0]2
1.4
6.2
ns
IRDYN
1.0
7.5
ns
RESET_OUTN2
2.1
7.3
ns
SD_CASN[3:0]_DMP[3:0]2
1.3
6.0
ns
SD_OEN_CASN2
1.4
5.9
ns
SDONEP
1.8
6.4
ns
SD_RASN[1:0]_CSN[1:0]2
1.3
5.9
ns
SD_WEN_WEN2
1.4
5.7
ns
STOPN
0.8
7.2
ns
T0_OUTN2
2.6
8.8
ns
(Sheet 1 of 2)
TinyRISC LR4102 Microprocessor
21
Table 11
AC Output Timing with respect to rising edge of
PBCLKP1 (Cont.)
Output Signal1
Min
Max
Units
T1_OUTN2
2.7
8.9
ns
TRDYN
0.8
7.2
ns
(Sheet 2 of 2)
1. With 65 pF load
2. This signal is related to the system clock, but not to the FAPI bus (see
Figure 5 note).
3. This signal is related to both the system clock and the FAPI bus (see
Figure 5 note).
Table 12
AC Output Timing with respect to rising edge of
SDCLKP1
Output Signal1
Min
Max
Units
FADDRP[28:0]
1.7
6.9
ns
FADP[31:0]
1.2
8.3
ns
SD_CASN[3:0]_DMP[3:0]
1.7
6.9
ns
SD_OEN_CASN
1.8
6.6
ns
SD_RASN
1.7
6.4
ns
SD_RASN[1:0]_CSN[1:0]
1.7
6.8
ns
SD_WEN_WEN
1.8
6.6
ns
1. With 65 pF load.
Table 13
AC Output Timing with respect to falling edge of TCK
Output Signal1
Min
Max
Units
TDO_TPC
2.1
8.9
ns
1. With 65 pF load
22
TinyRISC LR4102 Microprocessor
Table 14
1.
EZ4102 AC Output Timing with respect to rising edge of
DCLK1
Output Signal1
Min
Max
Units
PCST1[2:0]
−2.9
1.9
ns
TDO_TPC
−3.2
1.8
ns
TPC[4:2]
−3.2
2.0
ns
With 65 pF load.
Note:
there is no setup/hold time requirements for the interrupt
pins, INTP[5:0], because they are synchronized internally
within the LR4102.
Electrical Requirements
This section contains the electrical parameters for the TinyRISC LR4102
Microprocessor in the following tables:
•
Table 15 lists the absolute maximum ratings
•
Table 16 defines the recommended operating supply voltage and
temperature
•
Table 17 shows the pin capacitance
•
Table 18 lists the DC characteristics
Table 15
Absolute Maximum Rating1
Symbol
Parameter
Limits
Unit
VDD/DD2
DC Supply Voltage2, core and oscillator
−0.3 to 3.1
V
3.3 V DC Supply Voltage2, I/O
−0.3 to 3.9
V
−1.0 to VDD4 + 0.3
V
−40 to 125
˚C
VDD4
VIN
TSTG
3.3 V Drive Input Voltage2
Storage Temperature Range (Plastic)
1. Exceeding these values may cause damage to the LR4102.
2. Referenced to VSS.
TinyRISC LR4102 Microprocessor
23
Table 16
Recommended Operating Conditions
Symbol
VDD/DD2
TA
Parameter
DC Supply Voltage1
at VDD/VDD2 nominal 1.8 V
at VDD/VDD2 nominal 2.5 V
Ambient Temperature
Limits
Unit
1.71 to 1.89
2.38 to 2.63
V
V
0 to 70
˚C
1. Referenced to VSS.
Table 17
Capacitance
Symbol
Min
Typ
Max
Unit
Input Capacitance
4.6
–
5.2
pF
Output Capacitance
4.6
–
5.2
pF
Condition1
Min
Typ
Max
Units
Supply Voltage, I/O
–
3.0
3.3
3.6
V
VIL
Voltage Input Low
–
−0.5
–
0.8
V
VIH
Voltage Input High
–
2.0
–
VDD4
+ 0.3
V
IIL
Current Input Leakage
Inputs with no Pull-up/-down Resistor VIN = VSS/VDD4
Inputs with Pull-down Resistor
VIN = VDD4
Inputs with Pull-up Resistor
VIN = VSS
−10
35
−35
±1
115
−115
10
222
−214
µA
µA
µA
CIN
COUT
Table 18
Symbol
VDD4
Parameter
DC Characteristics
Parameter
VOL
Voltage Output Low
–
–
0.2
0.4
V
VOH
Voltage Output High
–
2.4
–
VDD4
V
IDD
Quiescent Supply Current
–
<1
20
100
µA
ICC
Dynamic Supply Current
–
–
170
–
mA
IOZ
Z-state Output Leakage Current
VOH = VSS/VDD4
−10
±1
10
µA
1. Specified at VDD4 equals 3.3 V ± 5% at ambient temperature over the specified range.
24
TinyRISC LR4102 Microprocessor
Pinouts
Table 19
Signal
Name
BIG_ENDIANP
CBEN0
CBEN1
CBEN2
CBEN3
CWAITIP1
CSHTSTP
DCLK
DEBUGMP
DEVSELN
DIVA0
DIVA1
DIVC0
DIVC1
EXTAL
FADDRP0
FADDRP1
FADDRP2
FADDRP3
FADDRP4
FADDRP5
FADDRP6
FADDRP7
FADDRP8
FADDRP9
FADDRP10
FADDRP11
FADDRP12
FADDRP13
FADDRP14
FADDRP15
FADDRP16
FADDRP17
FADDRP18
FADDRP19
FADDRP20
FADDRP21
FADDRP22
FADDRP23
FADDRP24
FADDRP25
FADDRP26
FADDRP27
FADDRP28
FADP0
FADP1
FADP2
FADP3
FADP4
FADP5
FADP6
Table 19 provides an alphabetical pinout list for the LR4102 256-pin
PBGA.
LR4102 256-pin PBGA Pinout
Solder
Ball
E18
A20
F18
Y9
W5
D10
B18
T1
P4
Y11
G17
K17
K18
L18
B16
K20
K19
L20
L19
M20
M19
N20
N19
P20
P19
R20
R19
T20
T19
U20
U19
V20
V19
W20
Y20
W19
Y19
V18
Y18
W18
Y17
W17
Y16
W16
B19
B20
C19
C20
D19
D20
E19
Signal
Name
FADP7
FADP8
FADP9
FADP10
FADP11
FADP12
FADP13
FADP14
FADP15
FADP16
FADP17
FADP18
FADP19
FADP20
FADP21
FADP22
FADP23
FADP24
FADP25
FADP26
FADP27
FADP28
FADP29
FADP30
FADP31
FALEP
FRAMEN
GNTN
GP0
GP1
GP2
GP3
GP4
GP5
GPIO0
GPIO1
GPIO2
GPIO3
GPRDN
GPWEN0
GPWEN1
GPWEN2
GPWEN3
ICECLKP
ICERXP
ICETXP
IDDTN
INTP0
INTP1
INTP2
INTP3
Solder
Ball
E20
F20
F19
G20
G19
H20
H19
J20
J19
W9
Y8
W8
Y7
W7
Y6
W6
Y5
Y4
W4
Y3
W3
Y2
W2
Y1
W1
Y13
W10
V2
V15
U14
V14
V13
U7
V6
T18
V16
V5
V3
U9
V10
V9
V8
V7
A8
B9
A9
D12
A13
B13
C13
A12
Signal
Name
Solder
Ball
INTP4
INTP5
IRDYN
JTAGALSOP
PBCLKP
PCST10
PCST11
PCST12
PLLENARSTP
PLLENP
PLLVDD1
PLLVSS1
PMON_OUTP
REQN
RESET_OUTN
RESETN
SCAN_ENABLEP
SCAN_INP
SCAN_MODEP
SCAN_OUTP
SCAN_RAMWEP
SD_CASN0_DMP0
SD_CASN1_DMP1
SD_CASN2_DMP2
SD_CASN3_DMP3
SD_OEN_CASN
SD_RASN
SD_RASN0_CSN0
SD_RASN1_CSN1
SD_WEN_WEN
SDCLKP
SDONEP
SELECT_CKOUT1N
SELECT_PLLN
STOPN
T0_OUTN
T1_OUTN
TCK
TDI_DINT
TDO_TPC
TMS
TN
TPC2
TPC3
TPC4
TRDYN
TRST
VDD
VDD2
VDD2
VDD2
TinyRISC LR4102 Microprocessor
A11
A10
Y10
C9
Y12
T3
R3
P3
G18
H18
A17
A18
B11
V1
A14
A15
C17
J18
C14
B17
D16
N18
P17
Y14
W14
M18
R18
P18
W15
M17
Y15
W13
B14
B15
W12
C10
B10
U1
T2
R2
U2
C11
R1
P2
P1
W11
N3
D14
L3
L4
T4
Signal
Name
VDD2
VDD2
VDD2
VDD2
VDD2
VDD2
VDD2
VDD2
VDD2
VDD2
VDD4
VDD4
VDD4
VDD4
VDD4
VDD4
VDD4
VDD4
VDD4
VDD4
VDD4
VDD4
VSS
VSS
VSS
VSS2
VSS2
VSS2
VSS2
VSS2
VSS2
VSS2
VSS2
VSS2
VSS2
VSS2
VSS2
VSS2
VSS4
VSS4
VSS4
VSS4
VSS4
VSS4
VSS4
VSS4
VSS4
VSS4
VSS4
VSS4
XTAL
Solder
Ball
U3
V11
U11
U16
V17
J 17
E17
D18
D5
C4
D6
D11
D15
F4
F17
K4
L17
R4
R17
U6
U10
U15
A1
C15
C16
D3
E4
M3
M4
V4
U5
V12
U12
U18
T17
C18
A19
D9
D4
D8
D13
D17
H4
H17
N4
N17
U4
U8
U13
U17
A16
25
Input/Output Drivers
Table 20 lists the I/O driver types.
Table 20
I/O Driver Types
Signal Name
I/O Driver Type Description
BIG_ENDIANP
IBUFULS
Input buffer with pull-up
CBEN[3:0]
BD12CLS
12 mA Bi-directional buffer
CSHTSTP
IBUFULS
Input buffer with pull-up
CWAITIP
BT8LS
8 mA output buffer
DCLK
BT24LS
24 mA output buffer
DEBUGMP
BT8LS
8 mA output buffer
DEVSELN
BD12CULS
12 mA Bi-directional buffer with pull-up
DIVA[1:0]
IBUFLS
Input buffer
DIVC[1:0]
IBUFLS
Input buffer
EXTAL, XTAL
OSCIM
Oscillator
FADDRP[28:0]
BT12LS
12 mA output buffer
FADP[31:0]
BD12CLS
12 mA Bi-directional buffer
FALEP
BT12LS
12 mA output buffer
FRAMEN
BD12CULS
12 mA Bi-directional buffer with pull-up
GNTN
BT12LS
12 mA output buffer
GP[5:0]
BD12SCUHO
12 mA Bi-directional buffer with
Schmidt trigger input and pull-up
GPIO[3:0]
BD12SCUHO
12 mA Bi-directional buffer with
Schmidt trigger input and pull-up
GPRDN
BT12LS
12 mA output buffer
GPWEN[3:0]
BT12LS
12 mA output buffer
ICECLKP
SCHMITCUHO
Schmidt trigger input with pull-up
(Sheet 1 of 3)
26
TinyRISC LR4102 Microprocessor
Table 20
I/O Driver Types (Cont.)
ICERXP
SCHMITCUHO
Schmidt trigger input with pull-up
ICETXP
BT6LS
6 mA output buffer
IDDTN
IIDDTNLS
IDD test input buffer
INTP[5:0]
IBUFULS
Input buffer with pull-up
IRDYN
BD12CULS
12 mA Bi-directional buffer with pull-up
JTAGALSOP
IBUFULS
Input buffer with pull-up
PBCLKP
BT8LS
8 mA output buffer
PCST[12:10]
BD8CDLS
8 mA Bi-directional buffer with pulldown
PLLENARSTP
IBUFLS
Input buffer
PLLENP
IBUFLS
Input buffer
PLLVDD1
PLLVDD
PLL Vdd
PLLVSS1
PLLVSS
PLL Vss
PMON_OUTP
PROCMONLS
PROCMON test output driver
REQN
IBUFULS
Input buffer with pull-up
RESET_OUTN
BT8LS
8 mA output buffer
RESETN
IBUFULS
Input buffer with pull-up
SCAN_ENABLEP
IBUFLS
Input buffer
SCAN_INP
IBUFLS
Input buffer
SCAN_MODEP
IBUFDLS
Input buffer with pull-down
SCAN_OUTP
BT8LS
8 mA output buffer
SCAN_RAMWEP
SCHMITCHO
Schmidt trigger input buffer
SD_CASN0_DMP0
BT12LS
12 mA output buffer
SD_CASN1_DMP1
BT12LS
12 mA output buffer
SD_CASN2_DMP2
BT12LS
12 mA output buffer
SD_CASN3_DMP3
BT12LS
12 mA output buffer
(Sheet 2 of 3)
TinyRISC LR4102 Microprocessor
27
Table 20
I/O Driver Types (Cont.)
SD_OEN_CASN
BT12LS
12 mA output buffer
SD_RASN
BT12LS
12 mA output buffer
SD_RASN0_CSN0
BT12LS
12 mA output buffer
SD_RASN1_CSN1
BT12LS
12 mA output buffer
SD_WEN_WEN
BT12LS
12 mA output buffer
SDCLKP
BT8LS
8 mA output buffer
SDONEP
BT12LS
12 mA output buffer
SELECT_CKOUT1N IBUFLS
Input buffer
SELECT_PLLN
IBUFLS
Input buffer
STOPN
BD12CULS
12 mA Bi-directional buffer with pull-up
T0_OUTN
BT8LS
8 mA output buffer
T1_OUTN
BT8LS
8 mA output buffer
TCK
IBUFULS
Input buffer with pull-up
TDI_DINT
IBUFULS
Input buffer with pull-up
TDO_TPC
BT8LS
8 mA output buffer
TMS
IBUFULS
Input buffer with pull-up
TN
IBUFULS
Input buffer with pull-up
TPC[4:2]
BD8CDLS
8 mA Bi-directional buffer with pulldown
TRDYN
BD12CULS
12 mA Bi-directional buffer with pull-up
TRST
IBUFULS
Input buffer with pull-up
(Sheet 3 of 3)
28
TinyRISC LR4102 Microprocessor
Package and Ordering Information
The LR4102 is available in a 256-lead Plastic Ball Grid Array (PBGA).
Table 21 provides the LR4102 order number and Figure 10 contains the
package mechanical drawing.
Table 21
LR4102 Ordering Information
Order Number
Clock Frequency
Package Type
Operating Range
L9A02121
85 MHz
256-lead PBGA
Commercial
1. Order number subject to change
Figure 10
LR4102 256 PBGA (IF) Mechanical Drawing
MD98.IF
Important:
This drawing may not be the latest version. For board layout and manufacturing, obtain the
most recent engineering drawings from your LSI Logic marketing representative by
requesting the outline drawing for package code IF.
TinyRISC LR4102 Microprocessor
29
Notes
30
TinyRISC LR4102 Microprocessor
Notes
TinyRISC LR4102 Microprocessor
31
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Printed on
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BM
Printed in USA
Order No. C14063.A
Doc. No. DB08-000082-01
This document is preliminary. As such, it contains data
derived from functional simulations and performance estimates. LSI Logic has not verified the functional descriptions
or electrical and mechanical specifications using production
parts.
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