ACT5270 [AEROFLEX]
ACT5270 64-Bit Superscaler Microprocessor; ACT5270 64位超标量微处理器型号: | ACT5270 |
厂家: | AEROFLEX CIRCUIT TECHNOLOGY |
描述: | ACT5270 64-Bit Superscaler Microprocessor |
文件: | 总5页 (文件大小:164K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
ACT5270
64-Bit Superscaler Microprocessor
Features
■ Full militarized QED RM5270 microprocessor
■ Integrated secondary cache controller (R5000 compatible)
● Supports 512K or 2MByte block write-through secondary
■ Dual Issue superscalar microprocessor - can issue one
integer and one floating-point instruction per cycle
● 133, 150, 200 MHz operating frequencies – Consult Factory for
latest speeds
■ High-performance floating point unit
● Single cycle repeat rate for common single precision operations
and some double precision operations
● 260 Dhrystone2.1 MIPS
● Two cycle repeat rate for double precision multiply and double
● SPECInt95 5.0, SPECfp95 5.3
precision combined multiply-add operations
● Single cycle repeat rate for single precision combined multiply-
add operation
■ High performance system interface compatible with RM5260,
R4600, R4700 and R5000
● 64-bit multiplexed system address/data bus for optimum price/
■ MIPS IV instruction set
performance with up to 100 MHz operating frequency
● Floating point multiply-add instruction increases performance in
signal processing and graphics applications
● High performance write protocols maximize uncached write
bandwidth
● Conditional moves to reduce branch frequency
● Index address modes (register + register)
● Supports clock divisors (2, 3, 4, 5, 6, 7, 8)
● 5V compatible I/O’s
■ Embedded application enhancements
● Specialized DSP integer Multiply-Accumulate instruction and 3
operand multiply instruction
● IEEE 1149.1 JTAG boundary scan
■ Integrated on-chip caches
● 16KB instruction - 2 way set associative
● I and D cache locking by set
● 16KB data - 2 way set associative
● Optional dedicated exception vector for interrupts
● Virtually indexed, physically tagged
■ Fully static CMOS design with power down logic
● Standby reduced power mode with WAIT instruction
● Write-back and write-through on per page basis
● Pipeline restart on first double for data cache misses
● 6 Watts typical at 3.3V 200 MHz
■ Integrated memory management unit
■ 208-lead CQFP, cavity-up package (F17)
● Fully associative joint TLB (shared by I and D translations)
■ 208-lead CQFP, inverted footprint (F24), Intended to duplicate
● 48 dual entries map 96 pages
the commercial QED footprint
● Variable page size (4KB to 16MB in 4x increments)
■ 179-pin PGA package (Future Product) (P10)
BLOCK DIAGRAM
Preliminary
Technology
eroflex Circuit
– RISC TurboEngines For The Future © SCD5270 REV 1 12/22/98
floating-point operations. Like the R5000, the
ACT5270 does virtual to physical translation in
parallel with cache access.
DESCRIPTION
The ACT5270 is a highly integrated superscalar
microprocessor that implements a superset of the
MIPS IV Instruction Set Architecture(ISA). It has a
high performance 64-bit integer unit, a high
throughput, fully pipelined 64-bit floating point unit,
an operating system friendly memory management
unit with a 48-entry fully associative TLB, a 16
KByte 2-way set associative instruction cache, a 16
KByte 2-way set associative data cache, and a
high-performance 64-bit system interface with
support for an optional external secondary cache.
The ACT5270 can issue both an integer and a
floating point instruction in the same cycle.
Integer Unit
As part of the ACT52xx family, the ACT5270
implements the MIPS IV Instruction Set
Architecture, and is therefore fully upward
compatible with applications that run on processors
implementing the earlier generation MIPS I-III
instruction sets. Additionally, the ACT5270 includes
two implementation specific instructions not found
in the baseline MIPS IV ISA but that are useful in
the embedded market place. Described in detail in
the QED RM5270 datasheet, these instructions are
integer multiply-accumulate and 3-operand integer
multiply.
The ACT5270 integer unit includes thirty-two
general purpose 64-bit registers, a load/store
architecture with single cycle ALU operations (add,
sub, logical, shift) and an autonomous multiply/
divide unit. Additional register resources include:
the HI/LO result registers for the two-operand
integer multiply/divide operations, and the program
counter(PC).
The ACT5270 is ideally suited for high-end
emb edded
internetworking,
control
high
applications
such
as
performance
image
manipulation, high speed printing, and 3-D
visualization.The ACT5270 is also applicable to the
low end workstation market where its balanced
integer and floating-point performance and direct
support for a large secondary cache (up to 2MB)
provide outstanding price/performance
HARDWARE OVERVIEW
Register File
The ACT5270 offers a high-level of integration
targeted
at
high-performance
embedded
The ACT5270 has thirty-two general purpose
registers with register location 0 hard wired to zero.
These registers are used for scalar integer
operations and address calculation. The register
file has two read ports and one write port and is fully
bypassed to minimize operation latency in the
pipeline.
applications. The key elements of the ACT5270 are
briefly described below.
Superscalar Dispatch
The ACT5270 has an efficient asymmetric
superscalar dispatch unit which allows it to issue an
integer instruction and a floating-point computation
instruction simultaneously. With respect to
superscalar issue, integer instructions include alu,
branch, load/store, and floating-point load/ store,
while floating-point computation instructions
include floating-point add, subtract, combined
multiply-add, converts, etc. In combination with its
high throughput fully pipelined floating-point
execution unit, the superscalar capability of the
ACT5270 provides unparalleled price/performance
ALU
The ACT5270 ALU consists of the integer adder/
subtractor, the logic unit, and the shifter. The adder
performs address calculations in addition to
arithmetic operations, the logic unit performs all
logical and zero shift data moves, and the shifter
performs shifts and store alignment operations.
Each of these units is optimized to perform all
operations in a single processor cycle.
in
computationally
intensive
embedded
applications.
CPU Registers
For additional Detail Information regarding the
operation of the Quantum Effect Design (QED)
Like all MIPS ISA processors, the ACT5270 CPU
has a simple, clean user visible state consisting of
32 general purpose registers, two special purpose
registers for integer multiplication and division, a
program counter, and no condition code bits.
RISCMark
ACT5270 , 64-Bit Superscalar
Microprocessor see the latest QED datasheet
(Revision 1.1 July 1998).
Pipeline
For integer operations, loads, stores, and other
non-floating-point operations, the ACT5270 uses
the simple 5-stage pipeline also found in the
ACT52xx family, R4600, R4700, and R5000. In
addition to this standard pipeline, the ACT5270
uses an extended seven stage pipeline for
2
Aeroflex Circuit Technology
SCD5270 REV 1 12/22/98 Plainview NY (516) 694-6700
Package Information – "F17" – CQFP 208 Leads
1.131 (28.727) SQ
1.109 (28.169) SQ
53
104
105
52
.010R MIN
.015 (.381)
.010R MIN
.009 (.229)
.130 (3.302)
MAX
1.009 (25.63)
.9998 (25.37)
51 Spaces at .0197
(51 Spaces at .50)
0°±5°
.100 (2.540)
.080 (2.032)
.009 (.253)
.007 (.178)
.035 (.889)
.025 (.635)
Detail "A"
1
156
157
Pin 1 Chamfer
Detail "A"
208
.055 (1.397)
REF
.115 (2.921)
MAX
.960 (24.384) SQ
REF
1.331 (33.807)
1.269 (32.233)
.055 (1.397)
.045 (1.143)
Units: Inches (Millimeters)
Note: Pin rotation is opposite of QEDs PQUAD due to cavity-up construction.
Future Package – "P10" – PGA 179 Pins (Advanced)
Bottom View
Side View
1
2
3
4
5
6
7
8
9 10 11 12 13 14 15 16 17 18
.100
BSC
V
U
T
R
P
N
M
L
1.700 1.840
BSC 1.880
K
J
.018
H
G
F
E
D
C
B
A
.050
1.700
BSC
.221
MAX
1.840
1.880
3
Aeroflex Circuit Technology
SCD5270 REV 1 12/22/98 Plainview NY (516) 694-6700
ACT5270 Microprocessor CQFP Pinouts – "F17"
Pin #
1
2
3
4
5
6
7
8
Function
Vcc (3.3V)
NC
NC
Vcc (3.3V)
Vss
Pin #
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
Function
NC
NC
NC
Vcc (3.3V)
Vss
ModeIn
RdRdy*
WrRdy*
ValidIn*
ValidOut*
Release*
VccP
Pin #
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
Function
Vcc (3.3V)
NMI*
ExtRqst*
Reset*
ColdReset*
VccOK
BigEndian
Vcc (3.3V)
Vss
SysAD16
SysAD48
Vcc (3.3V)
Vss
SysAD17
SysAD49
SysAD18
SysAD50
Vcc (3.3V)
Vss
SysAD19
SysAD51
Vcc (3.3V)
Vss
SysAD20
SysAD52
SysAD21
SysAD53
Vcc (3.3V)
Vss
SysAD22
SysAD54
Vcc (3.3V)
Vss
SysAD23
SysAD55
SysAD24
SysAD56
Vcc (3.3V)
Vss
SysAD25
SysAD57
Vcc (3.3V)
Vss
SysAD26
SysAD58
SysAD27
SysAD59
Vcc (3.3V)
Vss
Pin #
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
Function
NC
NC
NC
NC
Vcc (3.3V)
Vss
SysAD4
SysAD36
SysAD5
SysAD37
Vcc (3.3V)
Vss
SysAD6
SysAD38
Vcc (3.3V)
Vss
SysAD7
SysAD39
SysAD8
SysAD40
Vcc (3.3V)
Vss
SysAD9
SysAD41
Vcc (3.3V)
Vss
SysAD10
SysAD42
SysAD11
SysAD43
Vcc (3.3V)
Vss
SysAD12
SysAD44
Vcc (3.3V)
Vss
SysAD13
SysAD45
SysAD14
SysAD46
Vcc (3.3V)
Vss
SysAD15
SysAD47
Vcc (3.3V)
Vss
SysAD28
SysAD60
SysAD29
SysAD61
Vcc (3.3V)
Vss
SysAD30
SysAD62
Vcc (3.3V)
Vss
SysAD31
SysAD63
SysADC2
SysADC6
Vcc (3.3V)
Vss
SysADC3
SysADC7
Vcc (3.3V)
Vss
SysADC0
SysADC4
Vcc (3.3V)
Vss
SysADC1
SysADC5
SysAD0
SysAD32
Vcc (3.3V)
Vss
SysAD1
SysAD33
Vcc (3.3V)
Vss
SysAD2
SysAD34
SysAD3
SysAD35
Vcc (3.3V)
Vss
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
VssP
SysClock
Vcc (3.3V)
Vss
Vcc (3.3V)
Vss
Vcc (3.3V)
Vss
SysCmd0
SysCmd1
SysCmd2
SysCmd3
Vcc (3.3V)
Vss
SysCmd4
SysCmd5
Vcc (3.3V)
Vss
SysCmd6
SysCmd7
SysCmd8
SysCmdP
Vcc (3.3V)
Vss
Vcc (3.3V)
Vss
Vcc (3.3V)
Vss
Int0*
Int1*
Int2*
Int3*
Int4*
Int5*
ModeClock
JTDO
JTDI
JTCK
JTMS
Vcc (3.3V)
Vss
NC
NC
NC
NC
NC
NC
NC
Vcc (3.3V)
Vss
NC
NC
Vss
Vcc (3.3V)
Vss
NC
4
Aeroflex Circuit Technology
SCD5270 REV 1 12/22/98 Plainview NY (516) 694-6700
C IRC UIT TEC HNO LO G Y
Sample Ordering Information
Part Number
Screening
Speed (MHz)
Package
ACT-5270PC-133F17C
ACT-5270PC-150F17I
ACT-5270PC-200F17T
ACT-5270PC-200F17M
Commercial Temperature
Industrial Temperature
Military Temperature
Military Screened
133
150
200
200
208 Lead CQFP
208 Lead CQFP
208 Lead CQFP
208 Lead CQFP
Part Number Breakdown
ACT– 5270 PC – 200 F17 M
Aeroflex Circuit
Technology
Screening
Base Processor Type
C = Commercial Temp, 0°C to +70°C
I = Industrial Temp, -40°C to +85°C
T = Military Temp, -55°C to +125°C
M = Military Temp, -55°C to +125°C, Screened *
Q = MIL-PRF-38534 Compliant/SMD if applicable
Package Type & Size
Cache Style
PC = Primary Cache
Maximum Pipeline Freq.
133 = 133MHz
150 = 150MHz
200 = 200MHz
Surface Mount Package
F17 = 1.120" SQ 208 Lead CQFP
F24 = 1.120" SQ Inverted 208 Lead CQFP
Thru-Hole Package
P10 = 1.86"SQ PGA 179 pins with shoulder (Advanced)
*
Screened to the individual test methods of MIL-STD-883
Specifications subject to change without notice.
Telephone: (516) 694-6700
FAX: (516) 694-6715
Aeroflex Circuit Technology
35 South Service Road
Plainview New York 11803
www.aeroflex.com/act1.htm
Toll Free Inquiries: (800) 843-1553
E-Mail: sales-act@aeroflex.com
5
Aeroflex Circuit Technology
SCD5270 REV 1 12/22/98 Plainview NY (516) 694-6700
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