--
One of the fundamental lessons derived for the past successes of the semiconductor industry comes for the observation that most of the innovations of the past ten years—those that indeed that have revolutionized the way CMOS transistors are manufactured nowadays—were initiated 10–15 years before they were incorporated into the CMOS process. Strained silicon research began in the early 90s, high-?/metal-gate initiated in the mid-90s and multiple-gate transistors were pioneered in the late 90s. This fundamental observation generates a simple but fundamental question: “What should the ITRS do to identify now what the extended semiconductor industry will need 10–15 years from now?”
- International Technology Roadmap for Semiconductors 2012
More Moore
As we look at the years 2020–2025, we can see that the physical dimensions of CMOS manufacture are expected to be crossing below the 10 nanometer threshold. It is expected that as dimensions approach the 5–7 nanometer range it will be difficult to operate any transistor structure that is utilizing the metal-oxide semiconductor (MOS) physics as the basic principle of operation. Of course, we expect that new devices, like the very promising tunnel transistors, will allow a smooth transition from traditional CMOS to this new class of devices to reach these new levels of miniaturization. However, it is becoming clear that fundamental geometrical limits will be reached in the above timeframe. By fully utilizing the vertical dimension, it will be possible to stack layers of transistors on top of each other, and this 3D approach will continue to increase the number of components per square millimeter even when horizontal physical dimensions will no longer be amenable to any further reduction. It seems important, then, that we ask ourselves a fundamental question: “How will we be able to increase the computation and memory capacity when the device physical limits will be reached?” It becomes necessary to re-examine how we can get more information in a finite amount of space.
The semiconductor industry has thrived on Boolean logic; after all, for most applications the CMOS devices have been used as nothing more than an “on-off” switch. Consequently, it becomes of paramount importance to develop new techniques that allow the use of multiple (i.e., more than 2) logic states in any given and finite location, which evokes the magic of “quantum computing” looming in the distance. However, short of reaching this goal, a field of active research involves increasing the number of states available, e.g. 4–10 states, and to increase the number of “virtual transistors” by 2 every 2 years.
More than Moore
During the blazing progress propelled by Moore’s Law of semiconductor logic and memory products, many “complementary” technologies have progressed as well, although not necessarily scaling to Moore’s Law. Heterogeneous integration of multiple technologies has generated “added value” to devices with multiple applications, beyond the traditional semiconductor logic and memory products that had lead the semiconductor industry from the mid 60s to the 90s. A variety of wireless devices contain typical examples of this confluence of technologies, e.g. logic and memory devices, display technology, microelectricomechanical systems (MEMS), RF and Analog/Mixed-signal technologies (RF/AMS), etc.
The ITRS has incorporated More than Moore and RF/AMS chapters in the main body of the ITRS, but is uncertain whether this is sufficient to encompass the plethora of associated technologies now entangled into modern products, or the multi-faceted public consumer who has become an influential driver of the semiconductor industry, demanding custom functionality in commercial electronic products. In the next blog of this series, we will examine select data from the ITRS Overall Roadmap Technology Characteristics (ORTC) 2012 and attempt to extrapolate the progress in the next 15 years, and its potential impact.
The opportunities for more discourse on the impact and future of Moore’s Law on CS and other disciplines are abundant, and can be continued with your comments on the Research at Google Google+ page. Please join, and share your thoughts.
Related Post:
and
- MOOC Research and Innovation
- Collection of SQL queries with Answer and Output Set 2
- PiAUISuite Update and Voicecommand v3 1
- Sign in to edx org with Google and Facebook and
- Throwing fireballs with the Kinect and Oculus Rift in Unity 3D
- IT Laws and Patents notes for BSc IT Mumbai University
- How To Bypass Megaupload Wait Time And Download At Maximum Speed !!!
- The rise of the Bots Robots Surgeons and Disruptive Technology
- The Computer Science Pipeline and Diversity Part 2 Some positive signs and looking towards the future
- Collection of SQL queries with Answer and Output Set 4
- Skill maps analytics and more with Google’s Course Builder 1 8
- Why Watson and Siri Are Not Real AI
- PPT Presentation on Memory Management in Winnows2000 and WindowsXP
- Moore’s Law Part 1 Brief history of Moores Law and current state
- Information sharing for more efficient network utilization and management
- A year and a bit with Inbox Zero
- Explore the history of Pop and Punk Jazz and Folk with the Music Timeline
- Tips on Choosing Apt Web Templates and Service Providers
- Remembering to forget
- See through the clouds with Earth Engine and Sentinel 1 Data
- Teaching machines to read between the lines and a new corpus with entity salience annotations
- The Computer Science Pipeline and Diversity Part 1 How did we get here
- Getting your fridge to order food for you with a RPi camera and a hacked up Instacart API
- Google’s Course Builder 1 9 improves instructor experience and takes Skill Maps to the next level
- Sudoku Linear Optimization and the Ten Cent Diet
computer
- Take a better selfie with Lily
- Free Lecture The Psychology of Computer Insecurity
- MOOC Research and Innovation
- Calculating Ada The Countess of Computing
- When can Quantum Annealing win
- Creating a templated Binary Search Tree Class in C
- Projecting without a projector sharing your smartphone content onto an arbitrary display
- Will a robot take your job
- Facebook Introduces ‘Hack ’ the programming language of the future
- High Resolution Scary Haunted House Wallpapers for Desktop
- TYBSC IT Sem V Question Papers 2009 Mumbai University
- Home automation update
- Very easy to download youtube videos audio mp3 format
- HD Dark Desktop Background Wallpapers Download
- Launching the Quantum Artificial Intelligence Lab
- Syrias children learn to code with the Raspberry Pi
- Running omxplayer from the command line easily using alias
- Largest collection of Google Logos on the web Set 7
- Collection of SQL queries with Answer and Output Set 2
- Prevent access to specific partition or drive
- Summer Games Learn to Program
- PiAUISuite Update and Voicecommand v3 1
- Sign in to edx org with Google and Facebook and
- Large Scale Machine Learning for Drug Discovery
- Hacker Tricks from Insiders A Threat to ERP Systems
2
- Collection of SQL queries with Answer and Output Set 2
- The Computer Science Pipeline and Diversity Part 2 Some positive signs and looking towards the future
- A PPT Presentation on Web 2 0
- Text to Speech for low resource languages episode 2 Building a parametric voice
- Download Cool apple mac logo wallpaper for Desktop 2
- RPi Video Looper 2 0
- Medal of Honor 2 Heroes First Impressions
0 comments:
Post a Comment