Triple Level Metal 3.3V Operation 5.0V Compatible Input Buffers O
|
|
|
Top Searches for this datasheet
Drawn Gate Length (0.45µm Leff) Sea-of-Gates Architecture With
Triple Level Metal
3.3V Operation 5.0V Compatible Input Buffers On-chip Phase Locked Loop (PLL) Available Synthesize Frequencies
Manage Chip-to-Chip Clock Skew Compiled (gate level) Embedded (custom) SRAMs, CAMs Available 3.3V PCI, SCSI High Speed (250 MHz) Buffers Available Easy Alternative Sourcing Existing ASIC, FPGA Designs Design-for-Test methods Including JTAG, Serial Boundary Scan ATPG
Description
Atmel's next generation ATL50 Series CMOS Gate Arrays fabricated using 0.5µm drawn gate, oxide isolated, triple level metal process. Extensive cell libraries available support major software tools. with Atmel gate array families, customer involvement satisfaction integral steps design flow. variety Design Testability techniques supported libraries, wide range packaging options available.
Gate Arrays/ Embedded Arrays ATL50 Series Preliminary
ATL50 Array Organization
Device Number ATL50/4 ATL50/15 ATL50/25 ATL50/40 ATL50/60 ATL50/85 ATL50/110 ATL50/150 ATL50/200 ATL50/235 ATL50/300 ATL50/435 ATL50/550 ATL50/700 ATL50/870 ATL50/1100
Note:
Gates 4,000 15,000 25,000 38,000 58,000 86,000 110,000 149,000 195,000 232,000 301,000 430,000 545,000 693,000 870,000 1,119,000
Routable Gates 3,000 10,000 16,900 25,400 34,600 51,900 65,900 89,300 116,900 139,500 181,000 260,000 288,000 363,000 456,000 590,000
Count
Pins
Gate(1) Speed
Nominal Input NAND Gate volts
Rev. 0753B-11/99
Design
Design Systems Supported
Atmel supports several major software systems design with complete macro cell libraries, well utilities following design systems supported:
System Version 4.4.3 2.1.p2 4.1-s051 3.4B 5.2e Later 98.08, 98.05 Synopsys5.0.1A Exemplar Syntest
checki netlist accurate pre- route delay simulations.
Tools Opus- Schematic Layout Verilog- Verilog Simulator Pearl- Static Path Verilog-XL- Verilog Simulator Logic Design Planner- Floorplanner BuildGates- Synthesis (Ambit) Modelsim Verilog VHDL (VITAL) Simulator QuickVHDLVSS- VHDL Simulator Design Compiler- Synthesis Test Compiler- Scan Insertion ATPG Primetime- Static Path VCS- Verilog Simulator Leonardo Spectrum- Synthesis TurboCheck Gate TurboScan TurboFault
Cadence®
Mentor/Model Tech
1998.2f V2.2 V2.2 V1.6
Design Flow
Atmel provides three methods implementing gate array design, while maintaining same basic design flow each them. This flow involves both Customer Atmel critical review acceptance steps, seen from chart following page. Database Acceptance occurs when Atmel receives accepts complete design database. Atmel performs physical place-and-route. Functional timing simulations performed, based physical design, including generation back annotation report provide customer with most accurate timing information available. Final Design Review (FDR) last step design flow prior generation masks. After FDR, masks generated, wafers fabricated, prototype parts delivered.
ATL50
ATL50
ATL50 Gate Array Design Flow
Customer Kickoff Meeting
Atmel
Customer
Synthesis, Translation Conversion
Atmel
Customer
Database Submission
Atmel
Customer
Database Acceptance
Atmel
Physical Design Verification
Atmel
Customer
Final Design Review
Atmel
Customer
Prototype Delivery
Notes:
Performed customer optionally Atmel 9001 Milestone
Definition Requirements
Within Physical Design Step (i.e., layout) certain restrictions apply during definition. corner pins each reserved programmable Power Ground only. other buffer pins fully programmable Input, Output, Bidirectional, Clock-into-Array, Power Ground.
Motorola SMOSTM, Fujitsu others) into gate arrays. These designs have been optimized speed gate count modified logic memory, replicated pin-for-pin compatible, drop-in replacement.
FPGA Conversions
Atmel successfully translated existing FPGA/PLD designs from most major vendors (Xilinx®, Actel®, Altera®, Atmel) into Atmel ASICs. There four primary reasons convert from FPGA/PLD ASIC. Conversion high volume devices single combined design cost effective. Performance often optimized speed power consumption. Several FPGA/PLDs combined onto single chip minimize cost while reducing on-board space requirements. Finally, situations where FPGA/PLD used fast cycle time prototyping, ASIC provide lower cost answer long-term volume production.
Design Options
Logic Synthesis
Atmel accept Register Transfer Level (RTL) designs VHDL (MIL-STD-454, IEEE 1076) Verilog-HDLformat. Atmel fully supports Synopsys VHDL simulation well synthesis. VHDL Verilog-HDL Atmel's preferred method performing gate array design.
ASIC Design Translation
Atmel successfully translated dozens existing designs from most major ASIC vendors (LSI Logic
ATL50 Embedded Array
ATL50
ATL50
ATL50 Series Cell Library
Atmel's ATL50 Series gate arrays make extensive library cell structures, including logic cells, buffers inverters, multiplexers, decoders options. Soft macros also available. ATL50 Series operates frequencies with minimal phase error jitter, making ideal frequency synthesis high speed on-chip clocks chip-to-chip synchronization. Output buffers programmable meet voltage current requirements both SCSI. These cells well characterized SPICE modeling transistor level, with performance verified manufactured test arrays. Characterization performed over military temperature voltage ranges ensure that simulation accurately predicts performance finished product. Site Count(1)
Cell Index
Signal Name
ADD3X AND2 AND2H AND3 AND3H AND4 AND4H AND5 AOI22 AOI22H AOI222 AOI222H AOI2223 AOI2223H AOI23 BUF1 BUF2 BUF2T BUF2Z BUF3 BUF4 BUF4T BUF8 BUF12 BUF16 CLA7X DEC4 DEC4N DEC8N
Description
1-bit Full Adder with Buffered Outputs 2-input 2-input High-drive 3-input 3-input High-drive 4-input 4-input High-drive 5-input 2-input into 2-input 2-input into 2-input High-drive Two, 2-input ANDs into 2-input Two, 2-input ANDs into 2-input High-drive Three, 2-input ANDs into 3-input Three, 2-input ANDs into 3-input High-drive 2-input into 3-input Buffer Buffer Tri-state Driver with Active-high Enable Tri-state Driver with Active-low Enable Buffer Buffer Tri-state Driver with Active-high Enable Buffer Buffer Buffer 7-input Carry Lookahead Decoder Decoder with Active-low Enable Decoder with Active-low Enable
Cell Index (Continued)
Signal Name
DFFBCPX DFFBSRX DFFC DFFR DFFS DFFSR DLY1500 DLY2000 DLY3000 DLY6000 DSSBCPY DSSBR DSSBS DSSR DSSS DSSSR HLD1 INV1 INV1D INV1Q INV1TQ INV2 INV2T INV3 INV4 INV8 INV10 JKFBCPX JKFC LATBG
Description
Flip-flop Flip-flop with Asynchronous Clear Preset with Complementary Outputs Flip-flop with Asynchronous Reset with Complementary Outputs Flip-flop with Asynchronous Clear Flip-flop with Asynchronous Reset Flip-flop with Asynchronous Flip-flop with Asynchronous Reset Delay Buffer Delay Buffer Delay Buffer Delay Buffer Scan Flip-flop Scan Flip-flop with Clear Preset Scan Flip-flop with Reset Scan Flip-flop with Scan Flip-flop with Reset Scan Flip-flop with Scan Flip-flop with Reset Hold Cell Inverter Dual Inverters Quad Inverters Quad Tri-state Inverter Inverter Tri-state Inverter with Active-high Enable Inverter Inverter Inverter Inverter Flip-flop Clear Preset Flip-flop with Asynchronous Clear Preset Complementary Outputs Flip-flop with Asynchronous Clear LATCH LATCH with Complementary Outputs Inverted Gate Signal
Site Count(1)
ATL50
ATL50
Cell Index (Continued)
Signal Name
LATBH LATR LATS LATSR MUX2 MUX2H MUX2I MUX2IH MUX2N MUX2NQ MUX2Q MUX3I MUX3IH MUX4 MUX4X MUX4XH MUX5H MUX8 MUX8N MUX8XH NAN2 NAN2D NAN2H NAN3 NAN3H NAN4 NAN4H NAN5 NAN5H NAND5S NAN6 NAN6H NAN8 NAN8H NOR2 NOR2D
Description
LATCH with High-drive Complementary Outputs LATCH with Reset LATCH with LATCH with Reset High-drive with Inverted Output with Inverted Output High-drive with Active-low Enable Quad with Active-low Enable Quad with Inverted Output with Inverted Output High-drive with Transmission Gate Data Inputs with Transmission Gate Data Inputs High-drive High-drive with Active-low Enable with Transmission Gate Data Inputs High-drive 2-input NAND Dual 2-input NAND 2-input NAND High-drive 3-input NAND 3-input NAND High-drive 4-input NAND 4-input NAND High-drive 5-input NAND 5-input NAND High-drive 5-input NAND Single Stage 6-input NAND 6-input NAND High-drive 8-input NAND 8-input NAND High-drive 2-input Dual 2-input
Site Count(1)
Cell Index (Continued)
Signal Name
NOR2H NOR3 NOR3H NOR4 NOR4H NOR5 NOR5S NOR8 OAI22 OIA22H OAI222 OAI222H OAI22224 OAI23 ORR2 ORR2H ORR3 ORR3H ORR4 ORR4H ORR5 XNR2 XNR2H XOR2 XOR2H Note:
Description
2-input High-drive 3-input 3-input High-drive 4-input 4-input High-drive 5-input 5-input Single Stage 8-input 2-input into 2-input NAND 2-input into 3-input NAND High-drive Two, 2-input into 2-input NAND Two, 2-input into 2-input NAND High-drive Four, 2-input into 4-input NAND 2-input into 3-input NAND 2-input 2-input High-drive 3-input 3-input High-drive 4-input 4-input High-drive 5-input 2-input Exclusive 2-input Exclusive High-drive 2-input Exclusive 2-input Exclusive High-drive
Site Count(1)
single ATL50 routing site contains transistors, N-channel P-channel, aligned columns. number sites used gate varies according specific isolation power requirements. Percent utilization varies from 70%, with more accurate utilization figures generated DoubleCheckTM, Atmel's proprietary netlist checker.
ATL50
ATL50
Buffer Cell Index
Signal Name PBD2C PBC3C PBD5C PBS1C PBS1CS PBS2C PBS2CS PBS3C PBS3CS PBS4C PBS4CS PBS5C PBS5CS PBS6C PBS6CS PICI PICS PO2B PTD2 PTD3 PTD5 PTS1 PTS2 PTS3 PTS4 PTS5 PTS6 PX2CL PX2CR PX4CL PX4CR Description Bidi CMOS Buffer Bidi CMOS Buffer Bidi Buffer with Schmitt Trigger Bidi CMOS Buffer Bidi CMOS Buffer with Schmitt Trigger Bidi CMOS Input Buffer Bidi CMOS Input Buffer with Schmitt Trigger Bidi CMOS Buffer with Schmitt Trigger Bidi CMOS Buffer Bidi CMOS Buffer with Schmitt Trigger Bidi CMOS Buffer Bidi with Schmitt Trigger Bidi CMOS Buffer Bidi Schmitt Trigger CMOS Input Buffer CMOS Inverting Input Buffer CMOS Input Buffer with Schmitt Trigger Clock Driver Output Buffer Output Buffer Inverting Output Buffer Output Buffer Output Buffer Output Buffer Tri-state Output Buffer Tri-state Output Buffer Tri-state Output Buffer Tri-state Output Buffer Tri-state Output Buffer Tri-state Output Buffer Tri-state Output Buffer Tri-state Output Buffer Tri-state Output Buffer Crystal Oscillator Buffer (left side normalized input) Crystal Oscillator Buffer (right side normalized input) Crystal Oscillator Buffer (left side normalized input Crystal Oscillator Buffer (right side normalized input)
Absolute Maximum Ratings*
Operating Ambient Temperature.-55°C +125°C Storage Temperature .-65°C +150°C Voltage with Respect Ground .-2.0 +5.0V Maximum Operating Voltage .3.7V Note: *NOTICE: Stresses beyond those listed under "Absolute Maximum Ratings" cause permanent damage device. This stress rating only functional operation device these other conditions beyond those indicated operational sections this specification implied. Exposure absolute maximum rating conditions extended periods affect device reliability.
Minimum voltage -0.6V which undershoot -2.0 pulses less than Maximum output voltage 0.75V which overshoot +5.0V pulses less than
Volt Characteristics
Applicable over recommended operating range unless otherwise noted.
Symbol Parameter Buffer Test Condition VDD, VDD(max) VSS, VDD(max)), pull VSS, VDD(max), pull (33k VSS, VDD(max), pull VOUT VDD, VDD(max) VOUT VSS, VDD(max) 0.475VDD 0.325VDD rated, VDD(min) -500 rated, VDD(min)
0.7VDD 0.9VDD 0.1VDD
Units
Operating Temperature Supply Voltage High-level Input Current TTL, CMOS Low-level Input Current TTL, CMOS High-impedance State Output Current Output Short-circuit Current Buffer Buffer TTL, CMOS High-level Input Voltage CMOS Schmitt TTL, CMOS Low-level Input Voltage CMOS Schmitt VHYS Hysteresis High-level Output Voltage Low-level Output Voltage TTL, CMOS TTL, CMOS TTL, CMOS TTL, CMOS
-100
ATL50
ATL50
Buffer Characteristics
Symbol COUT CI/O Parameter Capacitance, Input Buffer (die) Capacitance, Output Buffer (die) Capacitance, Bidirectional Test Condition 3.3V 3.3V 3.3V Units
Buffers
Programmable output drive(1 IOL, 3.3V) 2,000 5,000 volts protection Programmable slew rate control Built-in configurable test logic fault coverage. This method requires only added pins Test Enable Test Mode. This easiest least expensive method designing testability into gate array design. means increasing testability gate array also available. Partitioning, memory array isolation, test point insertion encouraged supported ATL50 Series gate arrays. Atmel also encourages inclusion Built Self-Test (BIST) techniques whenever possible. Each these methods discussed detail Atmel CMOS Gate Array Design Manual. addition above, ATL50 Series gate arrays also support Joint Test Action Group (JTAG) boundary scan architecture Test Access Port (TAP) requirements. required soft hard macros implement IEEE 1149.1 compliant architecture available Atmel's cell library. JTAG architecture requires additional pins test mode, data, clock signals.
Design Testability
Atmel supports wide range Design Testability techniques improve percentage design that fully tested. achieving high degree testability, designer reduce design prototype debug time, minimize production test time, improve board system level test diagnostic capability. Synopsys Test Compiler software fully supported Atmel. this system during design, computer will create scan chains design, test vectors will generated provide greater than
Advanced Packaging
ATL50 Series gate arrays offered wide variety standard packages, including plastic ceramic quad flatpacks, thin quad flatpacks, ceramic grid arrays, ball grid arrays. High volume on-shore off-shore contractors provide assembly test commercial product, with prototype capability Colorado Springs. Custom package designs also available required meet customer's specific needs, supported through Atmel's package design center. When standard package cannot meet customer's need, package designed precisely application maintain performance obtained silicon. Atmel delivered custom-designed packages wide variety configurations.
Packaging Options
Package Type PQFP Power Quad L/TQFP PLCC CPGA CQFP PBGA Super Low-profile Mini Chip-scale Note:
Count 100, 120, 128, 132, 144, 160, 184, 208, 240, 144, 160, 208, 240, 100, 120, 128, 144, 160, 176, 100, 124, 144, 155, 180, 223, 224, 299, 100, 120, 132, 144, 160, 224, 121, 169, 208, 217, 225, 256, 272, 300, 304, 313, 316, 329, 352, 388, 420, 168, 204, 240, 256, 304, 352, 432, 560, 132, 144, 160, 180, 100,
Partial list
ATL50
Atmel Headquarters
Corporate Headquarters
2325 Orchard Parkway Jose, 95131 (408) 441-0311 (408) 487-2600
Atmel Operations
Atmel Colorado Springs
1150 Cheyenne Mtn. Blvd. Colorado Springs, 80906 (719) 576-3300 (719) 540-1759
Europe
Atmel U.K., Ltd. Coliseum Business Centre Riverside Camberley, Surrey GU15 England (44) 1276-686-677 (44) 1276-686-697
Atmel Rousset
Zone Industrielle 13106 Rousset Cedex France (33) 4-4253-6000 (33) 4-4253-6001
Asia
Atmel Asia, Ltd. Room 1219 Chinachem Golden Plaza Mody Road Tsimhatsui East Kowloon Hong Kong (852) 2721-9778 (852) 2722-1369
Japan
Atmel Japan K.K. Tonetsu Shinkawa Bldg. 1-24-8 Shinkawa Chuo-ku, Tokyo 104-0033 Japan (81) 3-3523-3551 (81) 3-3523-7581
Fax-on-Demand
North America: 1-(800) 292-8635 International: 1-(408) 441-0732
literature@atmel.com
Site
http://www.atmel.com
1-(408) 436-4309
Atmel Corporation 1999. Atmel Corporation makes warranty products, other than those expressly contained Company's standard warranty which detailed Atmel's Terms Conditions located Company's site. Company assumes responsibility errors which appear this document, reserves right change devices specifications detailed herein time without notice, does make commitment update information contained herein. licenses patents other intellectual property Atmel granted Company connection with sale Atmel products, expressly implication. Atmel's products authorized critical components life suppor devices systems. Marks bearing
and/or
registered trademarks trademarks Atmel Corporation. Printed recycled paper.
0753B-11/99/xM
Terms product names this document trademarks others.
Other recent searches
TPL9202 - TPL9202 TPL9202 Datasheet
SMR10PB1KH-TR - SMR10PB1KH-TR SMR10PB1KH-TR Datasheet
RCV144DPL - RCV144DPL RCV144DPL Datasheet
RCV144DPFL - RCV144DPFL RCV144DPFL Datasheet
NV-L50800A - NV-L50800A NV-L50800A Datasheet
LPC2210 - LPC2210 LPC2210 Datasheet
2220 - 2220 2220 Datasheet
LLV0603-FH - LLV0603-FH LLV0603-FH Datasheet
LLU1005 - LLU1005 LLU1005 Datasheet
GT10Q101 - GT10Q101 GT10Q101 Datasheet
AK4113 - AK4113 AK4113 Datasheet
2SK3878 - 2SK3878 2SK3878 Datasheet
2N5684 - 2N5684 2N5684 Datasheet
Privacy Policy | Disclaimer
© 2012 Datasheet Archive
