Upload
alvin-hoover
View
232
Download
0
Embed Size (px)
Citation preview
Design Methodology Semi Custom ASIC FPGA
VLSI Design Methodology
Silicon Foundry
IC Design Team
CAD Tool Provider
Design RulesSimulation Models and parameters
Mask LayoutsIntegrated circuits (IC)
Process Information Software Tools
Relationship between a silicon foundry, an IC design team and a CAD tool provider
Top Down(algorithm)
Bottom Up(physical)
IC
Standard IC ASSPs ASIC
Programmable IC Semi Custom IC Custom IC
FPGA Gate Array
Linear Array
Standard Cells
Full Custom
IC
ASSPs : Application Specific Standard Products
Application Specific Integrated Circuits (ASICs)
ASIC Design MethodologiesASIC Design Methodology
This approach is extremely slow, expensive
It is only used to design very high performance systems
Full-custom design
This approach is reasonable fast, less expensive
Most ASICs are currently designed using this method
Standard-cell based design
This approach is fast and less expensive
ASIC performance are relatively slow
Gate-array based design
The design process is very fast and cost effective
ASIC performance are slow
FPGA based design
ASIC-Benefit
• Improve performance• Reduce power consumption• Mix Analog and Digital Designs• Design optimization through IC
manufacturing process• Development Tools support HDL and
Schematic design approach
ASIC-Drawbacks
• Inflexible design• Deployed systems can not be upgraded• Mistakes in product development are costly• Updates requires a redesign• Complex and expensive development tools
11
Session Outline (FPGA)
Technology/price breakthrough in FPGA devices Why should Windows hardware developers care? Survey of new technologies/vendors Business comparison of FPGA with alternative
solutions Advantages/requirements for FPGA development
Case Studies Pleora iPort Pinnacle Studio Movie Box Deluxe
Summary/Conclusions
12
Technology Breakthrough Impacts Windows-Compatible Hardware Market Field Programmable Gate Arrays (FPGAs) break through
price/capability barriers 1 million gates drop from $200+ to <$20 90nm will offer another >2X improvement 32 bit RISC processors “for free”
Embedded “soft” 32-bit processors debut allowing complete System-on-Chip designs
Previously relegated to high-margin/low-volume applications
13
Why Should We Care?
Cost-effective FPGAs Enable New Windows-Compatible Products
Greater product differentiation Functionality and performance never available at
this price point Shorter development cycles = faster time to market Improved product flexibility = longer market life Reduced part inventory More product variants
14
New Low-Cost Technologies
FPGA Families Altera: Cyclone Xilinx: Spartan 3 QuickLogic:
QuickMIPS, Eclipse II Actel: ProASIC Plus
Embedded Processors Altera: Nios Xilinx: MicroBlaze QuickLogic: MIPS Actel: 8051
15
Three Choices For Windows-Compatible Hardware Development1. Develop conservative products based on
standard chipsets Little differentiation Minimal margin Straight to commodity
2. Develop an ASIC3. Use new FPGA technologiesLet’s compare options 2 and 3…
16
ASIC Versus FPGA Comparison Tooling cost Non-recurring
engineering costs (NRE)
Time to market Product risk Product flexibility Inventory
simplification
17
ASIC Versus FPGA Tools ASIC Requirements
Average seat of EDA tools $200K/engineer HDL Simulation, Synthesis, Timing analysis,
Test insertion, Place-and route, Formal verification, Floorplanning, DRC…
Usually involves multiple EDA vendors FPGA Requirements
Average seat $2K-$3K/yr Simulation, Synthesis, Place-and-route
Adequate tools provided by FPGA vendors Value-added tools from EDA vendors
~$20-30K
18
Non-Recurring Engineering (NRE) ASIC Designs
NRE for ASIC Designs ~$500K/run for .13µ Each subsequent re-spin costs another NRE For new 90nm technology NRE >$1M High-risk methodology requiring massive volume to recoup costs
FPGA Designs No NRE charges Some cost-reduction available by ASIC conversion with minimal
(<$100K) NRE Cost of FPGA device is offset by NRE in all but the
highest volume applications
19
Time To Market
ASIC Designs Typical design cycle 12-18 months, minimum 9 months Additional re-spins add 8-10 weeks each
FPGA Designs Typical design cycle 4 months Re-spins not an issue
20
Extremely FastTime-To-Prototype
Software-based prototype in days System assembly on FPGA in minutes
with processor, memory, bus,interfaces, peripherals
C/C++ based application (with RTOS if needed) running in minutes usingactual hardware
Iterative development/refinement flow Performance-critical routines easily
migrated to “hardware” implementations Software development in parallel with
working hardware Embedded “virtual instrumentation”
offers in-circuit debugging Allows evolutionary design style
21
Benefits Of FPGA-Based Design Improved product flexibility
Changes hardware/software up to (and even after) deployment
Inventoried parts can be re-deployed in multiple applications
More product variants on single platform Upgrade/enhance in the field
Reduce inventory Single part for multiple variations and versions of
product
22
What’s Needed For FPGA-Based Product Development?
Complete toolsets provided by FPGA vendors Robust libraries of pre-tested IP components
Processor cores (8,16,32 bit configurable) Peripherals (USB, PCI, I/O, DSP, ethernet, Memory…)
Ready-to-use development prototyping boards for a variety of application types
Development environments are PC/Windows-based, no UNIX workstations required
23
Case Study: Pleora iPort (~USD500) High-speed video-over-ethernet peripheral with Altera
Cyclone FPGA ~10X price/performance improvement over
frame-grabber solutions Gigabit ethernet versus expensive
video cabling Multiple video sources to single PC, or many-to-many Longer reach
24
Case Study: Pleora iPort
FPGA-based frame grabber low-cost, high-speed processing standardized (Ethernet) interfaces
Low cost-per-gate at high performance Flexible memory architecture for buffering Drop-in PCI core for interface with Intel
Network I/F
25
FPGA Benefits To Pleora
Reduced system cost Sub-$20 FPGA is 20% of product cost
Dramatically shorter design cycle Multiple product variants with single board
Inventory one part and deliver variations based on product mix
Enabler – ASIC-based solution not an option at target volumes
26
Pinnacle Studio MovieBox Deluxe (~USD 500)
“Without the FPGA option, we probably wouldn’t have pursued the project” - Bernd Riemann, Director Hardware
Engineering Pinnacle Systems GmbH
Uses Altera Cyclone FPGA for translation between video/audio I/O
Development time – 6 mos. with 2 engineers
ASIC solution would have added 1 year to development
FPGA ~20% of total BOM cost Using FPGA in more and more
projects
27
Pinnacle Studio MovieBox Deluxe
Remarkable leverage of FPGA reprogrammability 3 FPGAs in 1
Device hardware reconfigures itself based on operating mode Embedded memory sufficient for buffering – no external I/O required
Changes made right up to (and after) shipment Hardware design loaded at runtime from Windows drivers
Device shipped with no configuration on board User updates possible by downloading new drivers/patches
Feature set could be modified with no hardware changes Separate versions possible for NTSC, PAL, etc. Follow-on improvements could be added in future versions Business immunity from hardware design errors (and marketing
errors as well)
28
What Applications Benefit From FPGA?
Windows-compatible applications that challenge performance barriers…
High computational load: Digital Signal Processing (DSP) Video Digital TV Speech recognition
High embedded software content Embedded soft-cores offer unprecedented capability
29
What Does The Future Hold?
Tomorrow’s “Systems Designer” is today’s “Software Engineer”
Example: Nallatech, Ltd. of Scotland Prototyped entire system in C on embedded Xilinx
MicroBlaze SW engineer ran project Performance-critical modules moved into hardware
(FPGA fabric) New tools rolling out for C-based HW compilation Windows-compatible hardware becomes an
extension of SW applications development
30
Summary
FPGAs offer significant benefits to PC-based hardware development projects Reduced/more predictable development schedules Earlier prototypes Lower development cost More flexible, upgradeable products with longer
market life Greater capability/performance at lower price point Reduced BOM, more flexible inventory Reduced product risk
31
Community Resources
Community Sites http://www.microsoft.com/communities/default.mspx
List of Newsgroups http://communities2.microsoft.com/communities/newsgroups/en-u
s/default.aspx
Attend a free chat or webcast http://www.microsoft.com/communities/chats/default.mspx http://www.microsoft.com/seminar/events/webcasts/default.mspx
Locate a local user group(s) http://www.microsoft.com/communities/usergroups/default.mspx
Non-Microsoft Community Sites http://www.microsoft.com/communities/related/default.mspx