ETC QL4058

QL4058 QuickRAM Data Sheet
• • • • • • 58,000 Usable PLD Gate QuickRAM ESP Combining Performance,
Density and Embedded RAM
Device Highlights
Advanced I/O Capabilities
• Interfaces with both 3.3 V and 5.0 V devices
High Performance & High Density
• 58,000 Usable PLD Gates with 252 I/Os
• 300 MHz 16-bit Counters, 400 MHz
Datapaths, 160+ MHz FIFOs
• 0.35 µm four-layer metal non-volatile
CMOS process for smallest die sizes
• PCI compliant with 3.3 V and 5.0 V busses
for -1/-2/-3/-4 speed grades
• Full JTAG boundary scan
• I/O Cells with individually controlled
Registered Input Path and Output Enables
High Speed Embedded SRAM
• 18 dual-port RAM modules, organized in
user-configurable 1,152 bit blocks
• 5 ns access times, each port independently
accessible
• Fast and efficient for FIFO, RAM, and ROM
functions
18
RAM
Blocks
1,008
High Speed
Logic Cells
Easy to Use / Fast Development
Cycles
• 100% routable with 100% utilization and
complete pin-out stability
• Variable-grain logic cells provide high
performance and 100% utilization
• Comprehensive design tools include high
quality Verilog/VHDL synthesis
© 2002 QuickLogic Corporation
Interface
Figure 1: QuickRAM Block Diagram
www.quicklogic.com
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QL4058 QuickRAM Data Sheet Rev H
Architecture Overview
The QuickRAM family of ESPs (Embedded Standard Products) offers FPGA logic in
combination with Dual-Port SRAM modules. The QL4058 is a 58,000 usable PLD gate
member of the QuickRAM family of ESPs. QuickRAM ESPs are fabricated on a 0.35 µm
four-layer metal process using QuickLogic's patented ViaLinkTM technology to provide a
unique combination of high performance, high density, low cost, and extreme ease-of-use.
The QL4058 contains 1,008 logic cells and 18 Dual Port RAM modules (see Figure 1). Each
RAM module has 1,152 RAM bits, for a total of 20,736 bits. RAM Modules are Dual Port
(one read port, one write port) and can be configured into one of four modes:
64 (deep) × 18 (wide), 128 × 9, 256 × 4, or 512 × 2 (see Figure 4). With a maximum of
252 I/Os, the QL4058 is available in 208-PQFP, 240-pin PQFP, and 456-pin PBGA
packages.
Designers can cascade multiple RAM modules to increase the depth or width allowed in
single modules by connecting corresponding address lines together and dividing the words
between modules (see Figure 2). This approach allows up to 512-deep configurations as
large as 16 bits wide in the smallest QuickRAM device and 44 bits wide in the largest device.
Software support for the complete QuickRAM family, including the QL4058, is available
through two basic packages. The turnkey QuickWorksTM package provides the most
complete ESP software solution from design entry to logic synthesis, to place and route, to
simulation. The QuickTools package provides a solution for designers who use Cadence,
Exemplar, Mentor, Synopsys, Synplicity, Viewlogic, Aldec, or other third-party tools for
design entry, synthesis, or simulation.
The QuickLogicTM variable grain logic cell features up to 16 simultaneous inputs and five
outputs within a cell that can be fragmented into five independent cells. Each cell has a fanin of 29 including register and control lines (see Figure 3).
WDATA
RAM
Module
(1,152 bits)
WADDR
RDATA
RADDR
RAM
Module
(1,152 bits)
WDATA
RDATA
Figure 2: QuickRAM Module Bits
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© 2002 QuickLogic Corporation
QL4058 QuickRAM Data Sheet Rev H
Product Summary
Total of 252 I/O Pins
• 244 bi-directional input/output pins, PCI-compliant for 5.0 V and 3.3 V buses for
-1/-2/-3/-4 speed grades
• 8 high-drive input/distributed network pins
Eight Low-Skew Distributed Networks
• Two array clock/control networks available to the logic cell flip-flop clock, set and reset
inputs—each driven by an input-only pin
• Six global clock/control networks available to the logic cell F1, clock, set and reset inputs
and the input and I/O register clock, reset and enable inputs as well as the output enable
control—each driven by an input-only or I/O pin, or any logic cell output or I/O cell
feedback
High Performance Silicon
• Input + logic cell + output total delays = under 6 ns
• Data path speeds over 400 MHz
• Counter speeds over 300 MHz
• FIFO speeds over 160+ MHz
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QL4058 QuickRAM Data Sheet Rev H
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© 2002 QuickLogic Corporation
QL4058 QuickRAM Data Sheet Rev H
Electrical Specifications
AC Characteristics at VCC = 3.3 V, TA = 25°C (K = 1.00)
To calculate delays, multiply the appropriate K factor from Table 10: Operating Range by the
following numbers in the tables provided.
QS
A1
A2
A3
A4
A5
A6
AZ
QS
OP
B1
B2
C1
C2
MP
MS
OZ
QZ
D1
D2
E1
E2
NP
NS
NZ
F1
F2
F3
F4
F5
F6
FZ
QC
QR
Figure 3: QuickRAM Logic Cell
Table 1: Logic Cell
Symbol
tPD
Propagation Delays (ns)
Fanout (5)
Parameter
Combinatorial Delaya
a
1
2
3
4
5
1.4
1.7
1.9
2.2
3.2
1.7
1.7
1.7
1.7
1.7
tSU
Setup Time
tH
Hold Time
0.0
0.0
0.0
0.0
0.0
tCLK
Clock to Q Delay
0.7
1.0
1.2
1.5
2.5
tCWHI
Clock High Time
1.2
1.2
1.2
1.2
1.2
tCWLO
Clock Low Time
1.2
1.2
1.2
1.2
1.2
tSET
Set Delay
1.0
1.3
1.5
1.8
2.8
tRESET
Reset Delay
0.8
1.1
1.3
1.6
2.6
tSW
Set Width
1.9
1.9
1.9
1.9
1.9
tRW
Reset Width
1.8
1.8
1.8
1.8
1.8
a. These limits are derived from a representative selection of the slowest paths through the
QuickRAM logic cell including typical net delays. Worst case delay values for specific paths should
be determined from timing analysis of your particular design.
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QL4058 QuickRAM Data Sheet Rev H
[8:0]
WA
[17:0]
RE
RCLK
WD
WE
WCLK
[1:0]
[8:0]
RA
MODE
[17:0]
RD
ASYNCRD
Figure 4: QuickRAM Module
Table 2: RAM Cell Synchronous Write Timing
Symbol
Propagation Delays (ns)
Fanout
Parameter
1
2
3
4
5
tSWA
WA Setup Time to WCLK
1.0
1.0
1.0
1.0
1.0
tHWA
WA Hold Time to WCLK
0.0
0.0
0.0
0.0
0.0
tSWD
WD Setup Time to WCLK
1.0
1.0
1.0
1.0
1.0
tHWD
WD Hold Time to WCLK
0.0
0.0
0.0
0.0
0.0
tSWE
WE Setup Time to WCLK
1.0
1.0
1.0
1.0
1.0
tHWE
WE Hold Time to WCLK
0.0
0.0
0.0
0.0
0.0
5.0
5.3
5.6
5.9
7.1
tWCRD
WCLK to RD (WA=RA)
a
a. Stated timing for worst case Propagation Delay over process variation at VCC = 3.3 V and
TA = 25°C. Multiply by the appropriate Delay Factor, K, for speed grade, voltage and temperature
settings as specified in the Operating Range.
Table 3: RAM Cell Synchronous Read Timing
Symbol
Propagation Delays (ns)
Fanout
Parameter
Logic Cells
1
2
3
4
5
tSRA
RA Setup Time to RCLK
1.0
1.0
1.0
1.0
1.0
tHRA
RA Hold Time to RCLK
0.0
0.0
0.0
0.0
0.0
tSRE
RE Setup Time to RCLK
1.0
1.0
1.0
1.0
1.0
tHRE
RE Hold Time to RCLK
0.0
0.0
0.0
0.0
0.0
tRCRD
RCLK to RDa
4.0
4.3
4.6
4.9
6.1
a. Stated timing for worst case Propagation Delay over process variation at VCC = 3.3 V and
TA = 25°C. Multiply by the appropriate Delay Factor, K, for speed grade, voltage and temperature
settings as specified in the Operating Range.
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© 2002 QuickLogic Corporation
QL4058 QuickRAM Data Sheet Rev H
Table 4: RAM Cell Asynchronous Read Timing
Symbol
RPDRD
Propagation Delays (ns)
Fanout
Parameter
RA to RDa
1
2
3
4
5
3.0
3.3
3.6
3.9
5.1
a. Stated timing for worst case Propagation Delay over process variation at VCC = 3.3 V and
TA = 25°C. Multiply by the appropriate Delay Factor, K, for speed grade, voltage and temperature
settings as specified in the Operating Range.
Table 5: Input-Only / Clock Cells
Symbol
Propagation Delays (ns)
Fanout
Parameter
1
2
3
4
8
12
24
tIN
High Drive Input Delay
1.5 1.6 1.8 1.9 2.4 2.9 4.4
tINI
High Drive Input, Inverting Delay
1.6 1.7 .19 2.0 2.5 3.0 4.5
tISU
Input Register Set-Up Time
3.1 3.1 3.1 3.1 3.1 3.1 3.1
tIH
Input Register Hold Time
0.0 0.0 0.0 0.0 0.0 0.0 0.0
tICLK
Input Register Clock To Q
0.7 0.8 1.0 1.1 1.6 2.1 3.6
tIRST
Input Register Reset Delay
0.6 0.7 0.9 1.0 1.5 2.0 3.5
tIESU
Input Register Clock Enable Setup Time
2.3 2.3 2.3 2.3 2.3 2.3 2.3
tIEH
Input Register Clock Enable Hold Time
0.0 0.0 0.0 0.0 0.0 0.0 0.0
Table 6: Clock Cells
Symbol
Propagation Delays (ns)
Fanouta
Parameter
1
2
3
4
8
10
11
tACK
Array Clock Delay
1.2 1.2 1.3 1.3 1.5 1.6 1.7
tGCKP
Global Clock Pin Delay
0.7 0.7 0.7 0.7 0.7 0.7 0.7
tGCKB
Global Clock Buffer Delay
0.8 0.8 0.9 0.9 1.1 1.2 1.3
a. The array distributed networks consist of 40 half columns and the global distributed networks consist of 44 half columns, each driven by an independent buffer. The number of half columns used
does not affect clock buffer delay. The array clock has up to eight loads per half column. The global
clock has up to 11 loads per half column.
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QL4058 QuickRAM Data Sheet Rev H
Table 7: I/O Cell Input Delays
Symbol
Propagation Delays (ns)
Fanouta
Parameter
1
2
3
4
8
10
tI/O
Input Delay (bidirectional pad)
1.3
1.6
1.8
2.1
3.1
3.6
tISU
Input Register Set-Up Time
3.1
3.1
3.1
3.1
3.1
3.1
tIH
Input Register Hold Time
0.0
0.0
0.0
0.0
0.0
0.0
tIOCLK
Input Register Clock to Q
0.7
1.0
1.2
1.5
2.5
3.0
tIORST
Input Register Reset Delay
0.6
0.9
1.1
1.4
2.4
2.9
tIESU
Input Register Clock Enable Set-Up Time
2.3
2.3
2.3
2.3
2.3
2.3
tIEH
Input Register Clock Enable Hold Time
0.0
0.0
0.0
0.0
0.0
0.0
a. Stated timing for worst case Propagation Delay over process variation at VCC = 3.3 V and
TA = 25°C. Multiply by the appropriate Delay Factor, K, for speed grade, voltage and temperature
settings as specified in the Operating Range.
Table 8: I/O Cell Output Delays
Symbol
Propagation Delays (ns)
Output Load Capacitance (pF)
Parameter
3
50
75
100
150
tOUTLH
Output Delay Low to High
2.1
2.5
3.1
3.6
4.7
tOUTHL
Output Delay High to Low
2.2
2.6
3.2
3.7
4.8
tPZH
Output Delay Tri-state to High
1.2
1.7
2.2
2.8
3.9
tPZL
Output Delay Tri-state to Low
1.6
2.0
2.6
3.1
4.2
tPHZ
Output Delay High to Tri-state
a
2.0
-
-
-
-
tPLZ
Output Delay High to Tri-statea
1.2
-
-
-
-
a. These loads are used for tPXZ (see Figure 5)
tPHZ
1ΚΩ
5 pF
1ΚΩ
tPLZ
5 pF
Figure 5: Loads used for tPXZ
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© 2002 QuickLogic Corporation
QL4058 QuickRAM Data Sheet Rev H
DC Characteristics
The DC specifications are provided in the tables below.
Table 9: Absolute Maximum Ratings
Parameter
Value
Parameter
Value
VCC Voltage
-0.5 V to 4.6 V
DC Input Current
±20 mA
VCCIO Voltage
-0.5 V to 7.0 V
ESD Pad Protection
±2000 V
Input Voltage
-0.5 V to VCCIO +0.5 V
Storage Temperature
-65°C to +150°C
Latch-up Immunity
±200 mA
Lead Temperature
300°C
Table 10: Operating Range
Symbol
Parameter
Military
Industrial
Commercial
Unit
Min
Max
Min
Max
Min
Max
Supply Voltage
3.0
3.6
3.0
3.6
3.0
3.6
V
I/O Input Tolerance Voltage
3.0
5.5
3.0
5.5
3.0
5.25
V
TA
Ambient Temperature
-55
-
-40
85
0
70
°C
TC
Case Temperature
-
125
-
-
-
-
°C
-0 Speed Grade
0.42
2.03
0.43
1.90
0.46
1.85
n/a
-1 Speed Grade
0.42
1.64
0.43
1.54
0.46
1.50
n/a
-2 Speed Grade
0.42
1.37
0.43
1.28
0.46
1.25
n/a
-3 Speed Grade
0.43
0.90
0.46
0.88
n/a
-4 Speed Grade
0.43
0.82
0.46
0.80
n/a
VCC
VCCIO
K
Delay Factor
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QL4058 QuickRAM Data Sheet Rev H
Table 11: DC Characteristics
Symbol
Parameter
Conditions
Min
Max
Units
VIH
Input HIGH Voltage
0.5 VCC
VCCIO + 0.5
V
VIL
Input LOW Voltage
-0.5
0.3 VCC
V
VOH
Output HIGH Voltage
VOL
Output LOW Voltage
IOH = -12 mA
2.4
V
IOH = -500 µA
0.9VCC
V
IOL = 16 mAa
0.45
V
IOL = 1.5 mA
0.1 VCC
V
II
I or I/O Input Leakage Current
VI = VCCIO or GND
-10
10
µA
IOZ
3-State Output Leakage Current
VI = VCCIO or GND
-10
10
µA
10
pF
CI
IOS
ICC
ICCIO
Input Capacitanceb
Output Short Circuit Currentc
d
D.C. Supply Current
D.C. Supply Current on VCCIO
VO = GND
-15
-180
mA
VO = VCC
40
210
mA
VI, VIO = VCCIO or GND
0.50 (typ)
2
mA
0
100
µA
a. Applies only to -1/-2/-3/-4 commercial grade devices. These speed grades are also PCI-compliant. All
other devices have 8 mA IOL specifications.
b. Capacitance is sample tested only. Clock pins are 12 pF maximum.
c. Only one output at a time. Duration should not exceed 30 seconds.
d. For -1/-2/-3/-4 commercial grade devices only. Maximum ICC is 3 mA for -0 commercial grade and all
industrial grade devices and 5 mA for all military grade devices. For AC conditions, contact QuickLogic
customer applications group (see Contact Information)
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© 2002 QuickLogic Corporation
QL4058 QuickRAM Data Sheet Rev H
Kv and Kt Graphs
Voltage Factor vs. Supply Voltage
1.1000
1.0800
1.0600
Kv
1.0400
1.0200
1.0000
0.9800
0.9600
0.9400
0.9200
3
3.1
3.2
3.3
3.4
3.5
3.6
Supply Voltage (V)
Figure 6: Voltage Factor vs. Supply Voltage
Temperature Factor vs. Operating Temperature
1.15
1.10
1.05
Kt
1.00
0.95
0.90
0.85
-60
-40
-20
0
20
40
60
80
Junction Temperature C
Figure 7: Temperature Factor vs. Operating Temperature
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QL4058 QuickRAM Data Sheet Rev H
Power-up Sequencing
Voltage
VCCIO
VCC
(VCCIO -VCC)MAX
VCC
400 us
Time
Figure 8: Power-up Requirements
The following requirements must be met when powering up the device (see Figure 8):
• When ramping up the power supplies keep (VCCIO -VCC)MAX ≤ 500 mV. Deviation from
this recommendation can cause permanent damage to the device.
• VCCIO must lead VCC when ramping the device.
• The power supply must take greater than or equal to 400 µs to reach VCC. Ramping
to VCC/VCCIO earlier than 400 µs can cause the device to behave improperly.
An internal diode is present in-between VCC and VCCIO, as shown in Figure 9.
V CC
Internal Logic
Cells, RAM
blocks, etc
V CCIO
IO Cells
Figure 9: Internal Diode Between VCC and VCCIO
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© 2002 QuickLogic Corporation
QL4058 QuickRAM Data Sheet Rev H
JTAG
TCK
TMS
TRSTB
TAp Controller
State Machine
(16 States)
Instruction Decode
&
Control Logic
Instruction Register
RDI
Mux
Mux
TDO
Boundary-Scan Register
(Data Register)
Bypass
Register
Internal
Register
I/O Registers
User Defined Data Register
Figure 10: JTAG Block Diagram
Microprocessors and Application Specific Integrated Circuits (ASICs) pose many design
challenges. One of these challenges concerns the accessibility of test points. The Joint Test
Access Group (JTAG) formed in response to this challenge, resulting in IEEE standard
1149.1, the Standard Test Access Port and Boundary Scan Architecture.
The JTAG boundary scan test methodology allows complete observation and control of the
boundary pins of a JTAG-compatible device through JTAG software. A Test Access Port
(TAP) controller works in concert with the Instruction Register (IR); these allow users to run
three required tests, along with several user-defined tests.
JTAG tests allow users to reduce system debug time, reuse test platforms and tools, and reuse
subsystem tests for fuller verification of higher level system elements.
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QL4058 QuickRAM Data Sheet Rev H
The JTAG 1149.1 standard requires the following three tests:
• Extest Instruction. The Extest instruction performs a PCB interconnect test. This test
places a device into an external boundary test mode, selecting the boundary scan
register to be connected between the TAP's Test Data In (TDI) and Test Data Out (TDO)
pins. Boundary scan cells are preloaded with test patterns (via the Sample/Preload
Instruction), and input boundary cells capture the input data for analysis.
• Sample/Preload Instruction. This instruction allows a device to remain in its
functional mode, while selecting the boundary scan register to be connected between
the TDI and TDO pins. For this test, the boundary scan register can be accessed via a
data scan operation, allowing users to sample the functional data entering and leaving
the device.
• Bypass Instruction. The Bypass instruction allows data to skip a device's boundary
scan entirely, so the data passes through the bypass register. The Bypass instruction
allows users to test a device without passing through other devices. The bypass register
connects the TDI and TDO pins, allowing serial data to be transferred through a device
without affecting the operation of the device.
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© 2002 QuickLogic Corporation
QL4058 QuickRAM Data Sheet Rev H
Pin Descriptions
Table 12: Pin Descriptions
Pin
Function
Description
Test Data In for JTAG /RAM
init. Serial Data In
Hold HIGH during normal operation. Connects to
serial PROM data in for RAM initialization. Connect
to VCC if unused.
TRSTB/RRO
Active low Reset for JTAG
/RAM init. reset out
Hold LOW during normal operation. Connects to
serial PROM reset for RAM initialization. Connect to
GND if unused.
TMS
Test Mode Select for JTAG
Hold HIGH during normal operation. Connect to
VCC if not used for JTAG.
TCK
Test Clock for JTAG
Hold HIGH or LOW during normal operation.
Connect to VCC or ground if not used for JTAG.
Test data out for JTAG /RAM
init. clock out
Connect to serial PROM clock for RAM
initialization. Must be left unconnected if not used for
JTAG or RAM initialization.
Special Test Mode
Must be grounded during normal operation.
I/ACLK
High-drive input and/or array
network driver
Can be configured as either or both.
I/GCLK
High-drive input and/or global
Can be configured as either or both.
network driver
TDI/RSI
TDO/RCO
STM
I
High-drive input
Use for input signals with high fanout.
I/O
Input/Output pin
Can be configured as an input and/or output.
VCC
Power supply pin
Connect to 3.3 V supply.
Input voltage tolerance pin
Connect to 5.0 V supply if 5 V input tolerance is
required, otherwise connect to 3.3 V supply.
Ground pin
Connect to ground.
VCCIO
GND
GND/THERM Ground/Thermal pin
Available on 456-PBGA only. Connect to ground
plane on PCB if heat sinking desired. Otherwise may
be left unconnected.
Ordering Information
QL 4058 - 1 PQ208 C
QuickLogic device
QuickRAM device
part number
Speed Grade
0 = Quick
1 = Fast
2 = Faster
3 = Faster
*4 = Wow
Operating Range
C = Commercial
I = Industrial
M = Military
Package Code
PQ208 = 208-pin PQFP
PQ240 = 240-pin PQFP
PB456 = 456-pin PBGA
* Contact QuickLogic regarding availabliity
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QL4058 QuickRAM Data Sheet Rev H
208 and 240 PQFP Pinout Diagrams
Pin 157
Pin 1
QuickRAM
QL4058-1PQ208C
Pin 53
Pin 105
Figure 11: Top View of 208 Pin PQFP
Pin 181
Pin 1
QuickRAM
QL4058-1PQ240C
Pin 61
Pin 121
Figure 12: Top View of 240 Pin PQFP
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© 2002 QuickLogic Corporation
QL4058 QuickRAM Data Sheet Rev H
208 and 240 PQFP Pinout Table
Table 13: 208/240 PQFP Pinout Table
240
PQFP
208
PQFP
Function
240
PQFP
208
PQFP
Function
240
PQFP
208
PQFP
Function
240
PQFP
208
PQFP
Function
240
PQFP
208
PQFP
Function
1
208
I/O
2
1
I/O
51
43
GND
52
44
I/O
98
84
I/O
99
85
I/O
145
125
I/O
146
126
I/O
194
168
I/O
195
169
3
2
I/O
53
45
I/O
100
86
I/O
147
127
I/O
GND
196
NC
4
3
I/O
54
46
I/O
101
87
I/O
148
I/O
128
I/O
197
170
5
4
I/O
55
47
I/O
102
88
I/O
I/O
149
NC
I/O
198
171
6
5
I/O
56
48
I/O
103
89
I/O
I/O
150
129
GLCK/I
199
172
7
NC
I/O
57
NC
I/O
104
I/O
90
I/O
151
130
ACLK/I
200
173
8
6
I/O
58
49
I/O
I/O
105
91
I/O
152
131
VCC
201
174
9
7
I/O
59
50
I/O
I/O
106
92
I/O
153
132
GLCK/I
202
175
10
8
I/O
60
I/O
51
I/O
107
NC
I/O
154
133
GLCK/I
203
NC
11
9
I/O
I/O
NC
52
I/O
108
93
I/O
155
134
VCC
204
176
12
10
I/O
VCC
NC
53
I/O
109
94
I/O
156
135
I/O
205
177
GND
13
11
I/O
61
54
TDI
110
95
GND
157
136
I/O
206
178
I/O
14
12
GND
62
NC
I/O
NC
96
I/O
158
NC
I/O
207
179
I/O
15
13
I/O
63
NC
I/O
111
97
VCC
159
137
I/O
208
NC
I/O
16
14
I/O
64
55
I/O
NC
98
I/O
160
NC
GND
209
180
I/O
17
NC
I/O
65
56
I/O
NC
99
I/O
161
138
I/O
210
181
I/O
18
15
I/O
66
NC
I/O
112
100
I/O
162
139
I/O
211
182
GND
19
16
I/O
67
57
I/O
113
NC
I/O
163
140
I/O
212
NC
VCC
20
17
I/O
68
58
I/O
114
101
I/O
164
141
I/O
213
183
I/O
21
18
I/O
69
59
GND
115
NC
I/O
165
142
I/O
214
184
I/O
22
19
I/O
70
60
I/O
116
102
I/O
166
NC
I/O
215
185
I/O
23
20
I/O
71
61
VCC
117
NC
I/O
167
143
I/O
216
186
I/O
24
NC
I/O
72
62
I/O
118
NC
I/O
168
144
I/O
217
187
VCCIO
25
21
I/O
73
63
I/O
119
103
TRSTB
169
145
VCC
218
188
I/O
26
22
I/O
74
64
I/O
120
104
TMS
170
NC
I/O
219
NC
I/O
27
23
GND
75
NC
I/O
121
105
I/O
171
146
I/O
220
189
I/O
28
24
I/O
76
65
I/O
122
NC
I/O
172
147
GND
221
190
I/O
29
25
GCLK/I
77
66
I/O
123
106
I/O
173
148
I/O
222
191
I/O
30
26
ACLK/I
78
67
I/O
124
107
I/O
174
149
I/O
223
192
I/O
31
27
VCC
79
NC
I/O
125
108
I/O
175
150
I/O
224
193
I/O
32
28
GCLK/I
80
68
I/O
126
109
I/O
176
151
I/O
225
194
I/O
33
29
GCLK/I
81
69
I/O
127
NC
I/O
177
152
I/O
226
NC
I/O
34
30
VCC
82
70
I/O
128
110
I/O
178
153
I/O
227
195
I/O
35
31
I/O
83
NC
I/O
129
111
I/O
179
154
I/O
228
196
I/O
36
32
I/O
NC
71
I/O
130
112
I/O
180
155
I/O
229
197
I/O
37
NC
GND
84
NC
I/O
131
113
I/O
NC
156
I/O
230
198
I/O
38
33
I/O
85
72
I/O
132
114
VCC
181
157
TCK
231
NC
I/O
39
NC
I/O
86
73
GND
133
115
I/O
182
158
STM
232
199
GND
40
34
I/O
87
74
I/O
134
116
GND
183
NC
I/O
233
200
I/O
41
35
I/O
88
NC
VCC
135
117
I/O
184
159
I/O
234
201
VCC
42
36
I/O
89
75
I/O
136
NC
I/O
185
160
I/O
235
202
I/O
43
NC
I/O
90
76
I/O
137
118
I/O
186
161
I/O
236
203
I/O
44
37
I/O
91
77
I/O
138
119
I/O
187
162
I/O
237
204
I/O
45
38
I/O
92
78
GND
139
120
I/O
188
163
GND
238
205
I/O
46
39
I/O
93
79
I/O
140
121
I/O
189
164
I/O
239
206
I/O
47
NC
I/O
94
80
I/O
141
NC
I/O
190
165
VCC
240
207
TDO
48
40
I/O
95
81
I/O
142
122
I/O
191
166
I/O
49
41
VCC
96
82
I/O
143
123
I/O
192
NC
I/O
50
42
I/O
97
83
VCCIO
144
124
I/O
193
167
I/O
•
© 2002 QuickLogic Corporation
www.quicklogic.com •• 17
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•
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QL4058 QuickRAM Data Sheet Rev H
208 and 240 PQFP Mechanical Drawing
Figure 13: 208 PQFP Mechanical Drawing
18
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•
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© 2002 QuickLogic Corporation
QL4058 QuickRAM Data Sheet Rev H
456 PBGA Pinout Diagram
TOP View
QuickRAM
QL4058-1PB456C
BOTTOM View
PIN A1
CORNER
26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
AD
AE
AF
Figure 14: 456 PBGA Pinout Diagram
•
© 2002 QuickLogic Corporation
www.quicklogic.com •• 19
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QL4058 QuickRAM Data Sheet Rev H
456 PBGA Pinout Table
Table 14: 456 PBGA Pinout Table
456
Function
456
Function
456
Function
456
Function
456
Function
A1
I/O
C1
I/O
E1
I/O
H23
NC
M23
NC
A2
I/O
C2
I/O
E2
I/O
H24
I/O
M24
I/O
A3
I/O
C3
I/O
E3
I/O
H25
NC
M25
I/O
A4
I/O
C4
TDO
E4
I/O
H26
I/O
M26
I/O
A5
I/O
C5
I/O
E5
GND
J1
I/O
N1
GCLK/I
A6
I/O
C6
I/O
E6
VCC
J2
I/O
N2
I/O
A7
I/O
C7
I/O
E7
GND
J3
I/O
N3
I/O
A8
I/O
C8
I/O
E8
NC
J4
NC
N4
GCLK/I
A9
NC
C9
I/O
E9
GND
J5
GND
N5
VCC
A10
I/O
C10
I/O
E10
I/O
J22
NC
N11
GND/THERM
A11
I/O
C11
I/O
E11
GND
J23
NC
N12
GND/THERM
A12
VCCIO
C12
I/O
E12
GND
J24
I/O
N13
GND/THERM
A13
I/O
C13
I/O
E13
VCC
J25
I/O
N14
GND/THERM
A14
I/O
C14
I/O
E14
GND
J26
I/O
N15
GND/THERM
A15
NC
C15
I/O
E15
GND
K1
NC
N16
GND/THERM
A16
I/O
C16
I/O
E16
GND
K2
NC
N22
GND
A17
NC
C17
NC
E17
NC
K3
I/O
N23
I/O
A18
I/O
C18
NC
E18
GND
K4
I/O
N24
I/O
A19
I/O
C19
I/O
E19
NC
K5
VCC
N25
NC
A20
I/O
C20
I/O
E20
GND
K22
GND
N26
I/O
A21
NC
C21
I/O
E21
VCC
K23
I/O
P1
I/O
A22
I/O
C22
I/O
E22
GND
K24
I/O
P2
I/O
A23
NC
C23
I/O
E23
I/O
K25
NC
P3
NC
A24
I/O
C24
I/O
E24
I/O
K26
I/O
P4
I/O
A25
I/O
C25
TCK
E25
I/O
L1
I/O
P5
NC
A26
I/O
C26
NC
E26
I/O
L2
I/O
P11
GND/THERM
B1
I/O
D1
I/O
F1
I/O
L3
I/O
P12
GND/THERM
B2
NC
D2
I/O
F2
I/O
L4
I/O
P13
GND/THERM
B3
I/O
D3
I/O
F3
NC
L5
NC
P14
GND/THERM
B4
NC
D4
GND
F4
NC
L11
GND/THERM
P15
GND/THERM
B5
NC
D5
NC
F5
VCC
L12
GND/THERM
P16
GND/THERM
B6
NC
D6
NC
F22
VCC
L13
GND/THERM
P22
NC
B7
NC
D7
I/O
F23
NC
L14
GND/THERM
P23
GCLK / I
B8
NC
D8
I/O
F24
I/O
L15
GND/THERM
P24
GCLK / I
B9
I/O
D9
GND
F25
I/O
L16
GND/THERM
P25
NC
B10
NC
D10
I/O
F26
I/O
L22
NC
P26
ACLK / I
B11
NC
D11
I/O
G1
I/O
L23
I/O
R1
NC
B12
I/O
D12
GND
G2
I/O
L24
I/O
R2
I/O
B13
I/O
D13
I/O
G3
I/O
L25
NC
R3
I/O
B14
NC
D14
I/O
G4
I/O
L26
I/O
R4
NC
B15
I/O
D15
GND
G5
NC
M1
ACLK / I
R5
NC
B16
I/O
D16
I/O
G22
GND
M2
GCLK/I
R11
GND/THERM
B17
I/O
D17
I/O
G23
NC
M3
I/O
R12
GND/THERM
B18
I/O
D18
GND
G24
I/O
M4
NC
R13
GND/THERM
B19
I/O
D19
I/O
G25
I/O
M5
GND
R14
GND/THERM
B20
I/O
D20
NC
G26
I/O
M11
GND/THERM
R15
GND/THERM
B21
I/O
D21
NC
H1
NC
M12
GND/THERM
R16
GND/THERM
B22
I/O
D22
I/O
H2
I/O
M13
GND/THERM
R22
VCC
B23
NC
D23
GND
H3
NC
M14
GND/THERM
R23
NC
B24
I/O
D24
I/O
H4
I/O
M15
GND/THERM
R24
NC
B25
I/O
D25
I/O
H5
NC
M16
GND/THERM
R25
I/O
B26
STM
D26
I/O
H22
NC
M22
NC
R26
GCLK / I
(Sheet 1 of 2)
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© 2002 QuickLogic Corporation
QL4058 QuickRAM Data Sheet Rev H
Table 14: 456 PBGA Pinout Table (Continued)
456
Function
456
Function
456
Function
456
Function
456
Function
T1
I/O
W5
NC
AB15
VCC
AD3
I/O
AE17
I/O
T2
I/O
W22
NC
AB16
I/O
AD4
I/O
AE18
I/O
T3
I/O
W23
I/O
AB17
NC
AD5
I/O
AE19
I/O
T4
I/O
W24
I/O
AB18
VCC
AD6
I/O
AE20
I/O
T5
VCC
W25
I/O
AB19
GND
AD7
I/O
AE21
I/O
T11
GND/THERM
W26
NC
AB20
NC
AD8
I/O
AE22
NC
T12
GND/THERM
Y1
NC
AB21
VCC
AD9
NC
AE23
NC
T13
GND/THERM
Y2
I/O
AB22
GND
AD10
I/O
AE24
TMS
T14
GND/THERM
Y3
NC
AB23
I/O
AD11
NC
AE25
I/O
T15
GND/THERM
Y4
I/O
AB24
NC
AD12
I/O
AE26
I/O
T16
GND/THERM
Y5
I/O
AB25
I/O
AD13
I/O
AF1
I/O
T22
GND
Y22
GND
AB26
I/O
AD14
I/O
AF2
NC
T23
I/O
Y23
I/O
AC1
I/O
AD15
I/O
AF3
I/O
T24
I/O
Y24
NC
AC2
I/O
AD16
I/O
AF4
NC
T25
NC
Y25
I/O
AC3
NC
AD17
I/O
AF5
I/O
T26
I/O
Y26
I/O
AC4
GND
AD18
I/O
AF6
I/O
U1
NC
AA1
I/O
AC5
NC
AD19
NC
AF7
I/O
U2
I/O
AA2
I/O
AC6
NC
AD20
NC
AF8
I/O
U3
I/O
AA3
NC
AC7
NC
AD21
I/O
AF9
I/O
U4
I/O
AA4
NC
AC8
NC
AD22
I/O
AF10
I/O
U5
GND
AA5
VCC
AC9
NC
AD23
TRSTB
AF11
NC
U22
NC
AA22
VCC
AC10
NC
AD24
NC
AF12
I/O
U23
I/O
AA23
NC
AC11
I/O
AD25
I/O
AF13
I/O
U24
I/O
AA24
I/O
AC12
NC
AD26
I/O
AF14
NC
U25
I/O
AA25
I/O
AC13
I/O
AE1
TDI
AF15
NC
U26
I/O
AA26
I/O
AC14
VCCIO
AE2
I/O
AF16
I/O
V1
I/O
AB1
NC
AC15
NC
AE3
I/O
AF17
I/O
V2
I/O
AB2
I/O
AC16
NC
AE4
I/O
AF18
I/O
V3
NC
AB3
I/O
AC17
NC
AE5
I/O
AF19
NC
V4
NC
AB4
I/O
AC18
NC
AE6
I/O
AF20
I/O
V5
NC
AB5
GND
AC19
I/O
AE7
I/O
AF21
I/O
V22
GND
AB6
VCC
AC20
I/O
AE8
I/O
AF22
I/O
V23
NC
AB7
NC
AC21
I/O
AE9
I/O
AF23
I/O
V24
I/O
AB8
NC
AC22
NC
AE10
I/O
AF24
I/O
V25
NC
AB9
NC
AC23
GND
AE11
I/O
AF25
I/O
V26
I/O
AB10
VCC
AC24
NC
AE12
I/O
AF26
I/O
W1
I/O
AB11
GND
AC25
I/O
AE13
I/O
W2
I/O
AB12
NC
AC26
I/O
AE14
I/O
W3
I/O
AB13
I/O
AD1
I/O
AE15
I/O
W4
I/O
AB14
GND
AD2
NC
AE16
I/O
(Sheet 2 of 2)
•
© 2002 QuickLogic Corporation
www.quicklogic.com •• 21
•
•
•
QL4058 QuickRAM Data Sheet Rev H
456 PBGA Mechanical Drawing
Figure 15: 456 PBGA Mechanical Drawing
22
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• www.quicklogic.com
•
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•
© 2002 QuickLogic Corporation
QL4058 QuickRAM Data Sheet Rev H
Contact Information
Telephone:408 990 4000 (US)
416 497 8884 (Canada)
44 1932 57 9011 (Europe)
49 89 930 86 170 (Germany)
852 8106 9091 (Asia)
81 45 470 5525 (Japan)
E-mail: [email protected]
Support:[email protected]
Web site:http://www.quicklogic.com/
Revision History
Table 15: Revision History
Revision
Date
Comments
A
not avail.
First release.
B
not avail.
C
not avail.
D
not avail.
E
not avail.
F
not avail.
G
May 2000
Update of AC/DC Specs and reformat
H
May 2002
Added Kfactor, Power-up, JTAG and mechanical
drawing information. Reformatted.
Copyright Information
Copyright © 2002 QuickLogic Corporation.
All Rights Reserved.
The information contained in this product brief, and the accompanying software programs are protected by copyright. All rights are reserved by QuickLogic Corporation. QuickLogic Corporation
reserves the right to make periodic modifications of this product without obligation to notify any person or entity of such revision. Copying, duplicating, selling, or otherwise distributing any part of this
product without the prior written consent of an authorized representative of QuickLogic is prohibited.
QuickLogic, pASIC, and ViaLink are registered trademarks, and SpDE and QuickWorks are trademarks of QuickLogic Corporation.
Verilog is a registered trademark of Cadence Design Systems, Inc.
•
© 2002 QuickLogic Corporation
www.quicklogic.com •• 23
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