Semiconductor intellectual property core

In electronic design a semiconductor intellectual property core, IP core, or IP block is a reusable unit of logic, cell, or chip layout design that is the intellectual property of one party. IP cores may be licensed to another party or can be owned and used by a single party alone. The term is derived from the licensing of the patent and/or source code copyright that exist in the design. IP cores can be used as building blocks within ASIC chip designs or FPGA logic designs.

History

IP cores in the electronic design industry have had a profound impact on the design of systems on a chip. By licensing a design multiple times, an IP core licensor spreads the cost of development among multiple chip makers. IP cores for standard processors, interfaces, and internal functions have enabled chip makers to put more of their resources into developing the differentiating features of their chips. As a result, chip makers have developed innovations more quickly.

The licensing and use of IP cores in chip design came into common practice in the 1990s. There were many licensors and also many foundries competing on the market. Today, the most widely licensed IP cores are from ARM Holdings (43.2% market share in 2013), Synopsys Inc. (13.9% market share in 2013), Imagination Technologies (9% market share in 2013) and Cadence Design Systems (5.1% market share in 2013).[1]

Types of IP cores

The IP core can be described as being for chip design what a library is for computer programming or a discrete integrated circuit component is for printed circuit board design.

Soft cores

IP cores are typically offered as synthesizable RTL. Synthesizable cores are delivered in a hardware description language such as Verilog or VHSIC hardware description language (VHDL). These are analogous to high level languages such as C in the field of computer programming. IP cores delivered to chip makers as RTL permit chip designers to modify designs (at the functional level), though many IP vendors offer no warranty or support for modified designs.

IP cores are also sometimes offered as generic gate-level netlists. The netlist is a boolean-algebra representation of the IP's logical function implemented as generic gates or process specific standard cells. An IP core implemented as generic gates is portable to any process technology. A gate-level netlist is analogous to an assembly-code listing in the field of computer programming. A netlist gives the IP core vendor reasonable protection against reverse engineering.

Both netlist and synthesizable cores are called "soft cores", as both allow a synthesis, placement and route (SPR) design flow.

Hard cores

Hard cores, by the nature of their low-level representation, offer better predictability of chip performance in terms of timing performance and area.

Analog and mixed-signal logic are generally defined as a lower-level, physical description. Hence, analog IP (SerDes, PLLs, DAC, ADC, PHYs, etc.) are provided to chip makers in transistor-layout format (such as GDSII). Digital IP cores are sometimes offered in layout format, as well.

Such cores, whether analog or digital, are called "hard cores" (or hard macros), because the core's application function cannot be meaningfully modified by chip designers. Transistor layouts must obey the target foundry's process design rules, and hence, hard cores delivered for one foundry's process cannot be easily ported to a different process or foundry. Merchant foundry operators (such as IBM, Fujitsu, Samsung, TI, etc.) offer a variety of hard-macro IP functions built for their own foundry process, helping to ensure customer lock-in.

Sources of IP cores

Licensed functionality

Many of the best known IP cores are soft microprocessor designs. Their instruction sets vary from small 8-bit processors, such as the 8051 and PIC to 32-bit and 64-bit processors such as the ARM architectures or MIPS architectures. Such processors form the "brains" of many embedded systems.

IP cores are also licensed for a variety of peripheral controllers such as for PCI Express, SDRAM, Ethernet, LCD display, AC'97 audio, and USB. Many of those interfaces require digital logic as well as analog IP cores to drive and receive high speed, high voltage, or high impedance signals outside of the chip.

"Hardwired" (as opposed to software programmable soft microprocessors described above) digital logic IP cores are also licensed for fixed functions such as MP3 audio decode, 3D GPU, digital video decode, and other DSP functions such as FFT, DCT, or Viterbi coding.

Vendors

IP core developers and licensors range in size from individuals to multibillion-dollar corporations. Developers, as well as their chip making customers are located throughout the world.

Silicon Intellectual Property (SIP, Silicon IP) is a business model for a semiconductor company where the company licenses its technology to a customer as intellectual property. This is a type of fabless semiconductor company which doesn't provide physical chips to its customers but merely facilitates the customer's development of chips by offering certain functional blocks. Typically, the customers are semiconductor companies or module developers with in-house semiconductor development. A company wishing to fabricate a complex device may purchase the rights to use another company's well-tested functional blocks such as a microprocessor, instead of developing their own design which would take additional time and cost.

The Silicon IP industry is fairly new but with stable growth. The most successful Silicon IP companies, often referred to as the Star IP, include ARC International, ARM Holdings, Rambus and MIPS Technologies. Gartner Group estimated the total value of sales related to silicon intellectual property at US $1.5 billion in 2005, with annual growth expected around 30%.[2]

IP hardening

IP hardening is a process to re-use proven design, and generate fast time-to-market, low-risk-in-fabrication solutions to provide Intellectual property (IP) (or Silicon intellectual property) of design cores.

For example, a DSP processor is developed from soft cores of RTL (Register transfer level) format, and it can be targeted to various technologies or different foundries to yield different implementations. The process of IP hardening is from soft core to generate re-usable hard (hardware) cores. A main advantage of such hard IP is its predictable characteristics as the IP has been pre-implemented, while it offers flexibility of soft cores. It might come with a set of models for simulations or verifications.

The effort input to harden the soft IP means quality of the target technology, goals of design and the methodology employed. The hard IP has been proven in the target technology and application. E.g. the hard core in GDS II format is said to clean in DRC (Design rule checking), and LVS (see Layout Versus Schematic). I.e. that can pass all the rules required for manufacturing by the specific foundry.[3][4]

Free and open-source

OpenCores.org offers a wide variety of designs, mostly written in VHDL and Verilog. All of these cores are provided under some free and open-source software-license, e.g. GNU General Public License or BSD-like licenses.[5]

Aggregators

Intellectual property aggregators keep catalogs of cores from multiple vendors and provide search and marketing services to their customers.

See also

References

  1. Clark, Peter (April 23, 2014). "Cadence breaks into top four in semi IP core ranking". EE Times Europe (N/A). Peter Clark. European Business Press SA. Retrieved July 14, 2014.
  2. Kiat Seng Yeo, Kim Tean Ng, Zhi Hui Kong Intellectual Property for Integrated Circuits , J. Ross Publishing, 2010 ISBN 1-932159-85-1
  3. http://www.eettaiwan.com/ART_8800406094_480102_AN_71148c3a.HTM IP hardening by eetTaiwan Dead link 2011 06 30
  4. http://ic.hkstp.org/ip_mpw_ip.html More about IP hardening. An organization (which is set up by government) provides services of IP hardening and IP integration. In Chinese.
  5. OpenCores licenses
  6. Design and Reuse
  7. ChipEstimate
  8. Free ChipPath IP directory

External links

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