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OVONIC UNIFIED MEMORY Submitted by Submitted by Kirthi K Raman Kirthi K Raman 4PA06EC044 4PA06EC044 Under the guidance of Under the guidance of Prof. John.

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Presentation on theme: "OVONIC UNIFIED MEMORY Submitted by Submitted by Kirthi K Raman Kirthi K Raman 4PA06EC044 4PA06EC044 Under the guidance of Under the guidance of Prof. John."— Presentation transcript:

1 OVONIC UNIFIED MEMORY Submitted by Submitted by Kirthi K Raman Kirthi K Raman 4PA06EC044 4PA06EC044 Under the guidance of Under the guidance of Prof. John Valder Prof. John Valder P A College of Engg P A College of Engg

2 CONTENTS 1. Introduction 2. Present Memory Technology Scenario 3. Emerging Memory Technologies 4. Ovonic Unified Memory 5. OUM Attributes 6. OUM Architecture 7. Integration with Cmos 8. Circuit Demonstration 9. Advantages 10. Conclusion 11. Reference

3 Introduction Semiconductors form the fundamental building block of the modern electronic world. Semiconductors form the fundamental building block of the modern electronic world. Scaling of CMOS IC Technology faces uphill technology challenge. Scaling of CMOS IC Technology faces uphill technology challenge. For digital application, challenges include exponentially increasing leakage current, For digital application, challenges include exponentially increasing leakage current, short channel effects, etc. short channel effects, etc. For RF application, challenges include low noise figure, sustained linearity,transistor matching, power added efficiency, etc. For RF application, challenges include low noise figure, sustained linearity,transistor matching, power added efficiency, etc.

4 PRESENT MEMORY TECHNOLOGY SCENARIO Limitations DRAM is volatile and difficult to integrate. DRAM is volatile and difficult to integrate. RAM is expensive and volatile. RAM is expensive and volatile. Flash has slower writes and lesser number of write/erase cycle compared to others. Flash has slower writes and lesser number of write/erase cycle compared to others. These memory technologies when expanded allows expansion only in 2D. These memory technologies when expanded allows expansion only in 2D. Hence large area is required. Hence large area is required.

5 EMERGING MEMORY TECHNOLOGY Emerging memory technologies are called Next Generation Memories. Emerging memory technologies are called Next Generation Memories. Most important property of these NGM is its ability to support expansion in 3Dspace. Most important property of these NGM is its ability to support expansion in 3Dspace. NGM include NRAM, FeRAM, Polymer Memory Ovonic Unified Memory, ETOX, NRAM,etc. NGM include NRAM, FeRAM, Polymer Memory Ovonic Unified Memory, ETOX, NRAM,etc.

6 OVONIC UNIFIED MEMORY 1.OUM is a non volatile memory, which uses chalcogenide materials for storage of binary data. 2.OUM uses reversible structural phase change. amorphous phase crystalline phase. amorphous phase crystalline phase. 3. Resistive property of the phases is used to represent 0s and 1s. 3. Resistive property of the phases is used to represent 0s and 1s.

7 OUM Technology Concept Amorphous Vs Crystalline Amorphous Vs Crystalline Short Range Atomic Order Low Free Electron Density High Activation Energy High Resistivity Long Range Atomic Order High Free Electron Density Low Activation Energy Low Resistivity

8 OUM Technology Concept Annealing Dependence of Ge2Sb2Te5 Electrical Resistivity (ten minute isochronal anneal)

9 OUM Attributes density ensures large storage of data within a small area. Non volatile in nature. density ensures large storage of data within a small area. Non volatile in nature. High High Non destructive read Non destructive read Uses very voltage and power from a source. Uses very voltage and power from a source. Write/erase cycles of 10e12 demonstrated Write/erase cycles of 10e12 demonstrated Poly Crystalline Poly Crystalline Offers the potential of easy addition of non volatile memory to a standard CMOS processor Offers the potential of easy addition of non volatile memory to a standard CMOS processor Highly scalable memory Highly scalable memory Low cost implementation Low cost implementation

10 OUM Architecture

11 Cell Element Characteristics Basic Device Operation

12 IV Curve of Chalcogenide Element

13 Rset and Rreset as Function of Cell Current

14 Circuit Demonstration  Chalcogenide Technology Characterization Vehicle (CTCV)  Key goals in the design of CTCV 1. To make the read and write circuit wrt variation in cell electrical characteristics 1. To make the read and write circuit wrt variation in cell electrical characteristics 2. To test the effect of the memory cell layout on performance 2. To test the effect of the memory cell layout on performance 3. To maximize the amount of useful data obtained, used for product design. 3. To maximize the amount of useful data obtained, used for product design.

15 One of the Chiplet used fig Conservative FET Cell Single Ended Sense Amp Aggressive FET Cell Single Ended Sense Amp Conservative FET Cell Differential Sense Amp Aggressive FET Cell Differential Sense Amp Process Monitor Circuits

16 Advantages OUM uses a reversible structural phase change OUM uses a reversible structural phase change Cost/Bit reduction Cost/Bit reduction small active storage medium small active storage medium small cell size-small die size small cell size-small die size Simple manufacturing process Simple manufacturing process Simple planar device structure Simple planar device structure Low voltage-single supply Low voltage-single supply Reduced assembly and test costs Reduced assembly and test costs Highly scalable Highly scalable Performance improves with scaling Performance improves with scaling Only lithography limited Only lithography limited Low voltage operation Low voltage operation Multi state demonstrated Multi state demonstrated

17 Risk Factors Reset current< min W switch current Reset current< min W switch current Standand CMOS process integration Standand CMOS process integration Alloy optimization for robust high temp operation and speed Alloy optimization for robust high temp operation and speed Cycle life endurance consistency Cycle life endurance consistency Endurance testing to 1014-DRAM Endurance testing to 1014-DRAM Defect density and failure mechanisms Defect density and failure mechanisms

18 Conclusion Near ideal memory qualities Near ideal memory qualities Broadens system application Broadens system application -Embedded System-On-a-Chip(SOC), other products -Embedded System-On-a-Chip(SOC), other products Highly Scalable Highly Scalable Risk factors have been identified Risk factors have been identified Time to productize Time to productize

19 References 1. www.intel.com www.intel.com 2. www.ovonyx.com www.ovonyx.com 3. www.baesystems.com www.baesystems.com 4. www.aero.org www.aero.org 5. IEEE SPECTRUM, March 2003

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