High Speed Interface for Various Applications I.

Overview

II. Interface Basics

III. Applications IV. Closer Look V. Conclusion 2011. 4.27

LG Electronics / Kirt Hong

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1. Overview • Why High Speed Interface? • Evolution of Interface Standard

1. Overview

Why High Speed Interface?

• Current system performance is hampered by Inter-Component Interface rather than Intra-Chip Technology.

1) Chip-to-Chip Interface 2) Board-to-Board Interface 3) Box-to-Box Interface 4) Memory Interface

1)

4)

2)

4) HDD

3) 3)

1. Overview

Why High Speed Interface?

• Bigger display and higher resolution drastically increase the pixel data to be transmitted over cables. 640 480

VGA

1280 720

HD

1920

1080

3840

FHD 2160

X3

4K x 2K

X2.25 X4

If LVDS, lane count (10-bit, 120Hz) is 12 lanes

Too Many!! 24 lanes

96 lanes

1 lane = 2 lines

1. Overview

Evolution of Interface Standard

PATA first appeared in Compaq PC (1986)

First SATA introduced (2003)

Market starts to adopt USB (1998)

PCIe replaced PCI & AGP (2004)

DP introduced (2006) eDP released (2008) 1995

2000

2005

2010

LVDS introduced (1994) DVI introduced (1999) LCD panel uses Mini-LVDS (2001)

Vx1 HS released (2008) iDP approved (2010)

DVI evolved to HDMI (2002) MIPI alliance formed (2003) Qualcomm developed MDDI (2004)

CE interface

Mobile Interface

PC Interface

1. Overview

Lane Speed (Gbps)

Data Rate Comparison between Various Interface Standards

WiGig

Wired External I/F

Wired Internal I/F

Wireless External I/F

6 DP 5

DiiVA WirelessHD Vx1 HS

4 HDMI

iDP

3

2

WHDI HS LVDS UWB

1 WiFi

Application

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2. Interface Basics • “Am I wide enough?” • “How do I look?” • “Where is my Clock?” • “What’s the matter?”

• “Let’s make it faster!”

2. Interface Basics

“Am I wide enough?”

Parallel

vs.

Serial

 Familiar and quickly implemented

 Much higher speed

 Fast reaction time

 No skew : Longer distance

 No Link layer required

 Clock embedded in data

 Source synchronous clock required

 Reduction of signal line counts

 Skew between data lines

 Heavy Link layer

Data

Data TX

Clock

Data

Data

RX Clock

Data TX

Clock

Clock

Data w/ Clock

RX Clock

2. Interface Basics

“How do I look?”

Network Topologies Point-to-Point

Multi-drop

Multipoint

 Single TX & Single RX

 Single TX & Multiple RX

 Multiple TX & Multiple RX

 HDMI, DisplayPort

 M-LVDS, B-LVDS

 M-LVDS, B-LVDS

TX TX

RX3

TX1

RX3

RX RX1

RX2

RX1

RX2

TX2

TX3

2. Interface Basics

Explicit Clock

“Where is my Clock?”

vs. Embedded Clock

 Intuitive

 Implicit

 Setup/Hold window check

 Eye diagram check

 Clock Skew to data

 Free from skew problem

 Easy Physical layer design

 Routing flexibility

 Ex) LVDS

 Extra encoding required (ex, 8b10b)  Clock Recovery circuit required  Ex) DisplayPort

Clock Data

Data + Clock

2. Interface Basics

“What’s the matter?”

Speed Limiting Factors  Capacitive Loading from pad and lead frame

 Reflection from Transmission Line Discontinuity  Attenuation from Dielectric Loss  Crosstalk caused by adjacent signal line  Timing Skew between parallel signals  Simultaneous Switching Noise (SSN)  Inter-Symbol Interference (ISI)

2. Interface Basics

“Let’s make it faster!”

To Increase the Data Rate  Differential signaling

 Pre-emphasis and Equalization

Before Equalization

After Equalization

 Point-to-Point Topology rather than Multi-drop Topology  Capacitive Coupling control

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3. Applications • Digital TV • Mobile • PC • Wireless

3. Applications

Digital TV

 External Interface : HDMI, DP, DIIVA  Internal Interface : HS-LVDS, iDP, V-by-One HS

 Panel Interface : Mini-LVDS, EPI

Panel DIC

Panel Interface

It may be one-chip External Interface

CE

Main SoC

Internal Interface

Internal Interface

FRC / 3D

TCON

3. Applications

Mobile

 MIPI Interface RF

DigRF

DSI

BB

Display Driver

DSI

Camera Driver

CSI

Display

LLI

WLAN

UniPort

CSI AP

CIS

SLIMbus Speaker UFS

Mass Storage

SPMI UniPort (UniPro + D-PHY/M-PHY) PMU DSI (Display Serial Interface) CSI (Camera Serial Interface) SPMI (System Power Management Interface) SLIMbus (Serial Low-power Inter-chip Media Bus) LLI (Low Latency Interface) / BIF (Battery Interface)

BIF

Mic. Ear Piece FM Radio

Battery

BlueTooth GPS

3. Applications

PC

FSB (Front Side Bus) AGP (Accelerated Graphics Port) SATA (Serial Advanced Technology Attachment) PCI (Peripheral Component Interconnect) PCIe (PCI Express)

Graphics

AGP PCIe

SATA HDD

CPU FSB Memory Control (Northbridge)

DDR2 DDR3 DRAM

PCIe I/O Control (Southbridge)

Local I/O

USB

USB port PCIe PCI Mobile Ducking

Gigabit Ethernet

Add-on Card

PCI slots

3. Applications

Wireless

 How They Are Connected Network

Monitor

How to travel

Laptop

Mobile TV

P2P

STB

PDA Printer

Tablet Photo Frame

PC

Wired

PLC

MoCA

Game NAS Tablet

Cellphone BDP

Camera PLC (Power Line Communication) MoCA (Multimedia over Coax Alliance) NAS (Network Attached Storage)

Wireless

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4. Closer Look • Box-to-Box Interface • Chip-to-Chip Interface • Memory Interface • Wireless Interface • Optical Link Interface

4. Closer Look

Box-to-Box Interface

HDMI • • • • •

Initial release in 2002; Currently HDMI 1.4 released in 2009 Industry de facto standard for Consumer Electronics Networking feature added (LiquidHD) Companion Interface Standard introduced (MHL, SPMT) Needs royalty / licensing fee

Network

CE TV

Mobile

TV1

Home Theater

TV2 HDMI (High-Definition Multimedia Interface), MHL (Mobile High-definition Link), SPMT (Serial Port Memory Technology)

4. Closer Look

Box-to-Box Interface

DisplayPort (DP) • • • • •

Initial released by VESA in 2006; currently DP 1.2 in 2010 Intended for both External and Internal interfaces Open standard; royalty-free Several Derivatives : eDP, iDP, tDP PC & Monitor application

External Interface

CE

Internal Interface Monitor

Graphics

TCON

VESA (Video Electronics Standards Association), eDP (Embedded DP), iDP (Internal DP), tDP (TCON DP)

Panel

4. Closer Look

Box-to-Box Interface

DIIVA (also known as DIVA) • Initial released by DIIVA Consortium in 2009 • Originally designed for Home Entertainment Networking : Unification of 3 packet types (Video, Data, Power Control) • Flexible connection (Daisy Chain or Switch configuration) • Operating over standard Ethernet cable • Under promotion

DIIVA Daisy Chain

CAT6A

DIIVA (Digital Interactive Interface for Video and Audio), DIVA (Digital Interface for Video and Audio)

DIIVA Switch

4. Closer Look

Comparison

HDMI

DisplayPort

DIIVA

First Release

2002

2006

2009

Current version

HDMI 1.4

DP 1.2

DIIVA 1.0a

Controlling Authority

HDMI LLC

VESA

DIIVA Promoter

Content Protection

HDCP

DPCP / HDCP

HDCP / DTCP-IP

Bit rate / pair

Up to 3.4Gbps

1.62/2.7/5.4Gbps

4.5Gbps

Max. total capacity

10.2Gbps

21.6Gbps

13.5Gbps

No. of clock ch.

1

0

0

No. of video ch.

3

1/2/4

3

AUX channel

DDC

AUX

Hybrid Link

Channel coding

TMDS

8b/10b

8b/10b

Major Application

TV

Monitor

Home Networking

Ethernet

100Mbps

720Mbps

Gigabit

USB

No

Yes

Yes

Remarks

Bidirectional Power Over DIIVA

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4. Closer Look • Box-to-Box Interface • Chip-to-Chip Interface • Memory Interface • Wireless Interface • Optical Link Interface

4. Closer Look

Chip-to-Chip Interface

Categorization of Internal Interface • TCON Interface : LVDS, HS-LVDS, iDP, V-by-One HS • Panel Interface : Mini-LVDS, EPI, MIPI, MDDI

Large Panel

Small Panel

Driver ICs

Driver ICs

Panel Interface

TCON Interface Graphics

TCON

Panel Interface

TCON

4. Closer Look

Chip-to-Chip Interface

LVDS • • • •

Introduced by ANSI/TIA/EIA-644 in 1994 Low voltage swing (350mV) and DC-balancing Data Rate : 7X the original pixel clock Various LVDS Technologies : LVPECL, CML, MLVDS, BLVDS, HS-LVDS

LVPECL Power Consumption

CML LVDS

100M

1G

3G

5G

Data Rate (bps)

10G

LVDS (Low-Voltage Differential Signaling) LVPECL (Low-Voltage Positive-Emitter-Coupled Logic) CML (Current Mode Logic) MLVDS (Multipoint LVDS) BLVDS (Bus LVDS) HS-LVDS (High Speed LVDS)

4. Closer Look

Chip-to-Chip Interface

iDP (Internal DisplayPort) • • • •

Initial released by VESA in 2010 Open standard led by LG Display and STM Targeted for interconnecting TV/Monitor SoC and TCON Only video data transfer by leveraging the DP technology

LVDS Interface

iDP Interface

Fixed Rate (3.24Gbps) FRC

TCON

48 lanes for FHD 240Hz

TCON

FRC

8 lanes for FHD 240Hz

4. Closer Look

Chip-to-Chip Interface

V-by-One HS • • • •

Authority to control standard belongs to THine Removed Link Logic by Variable bit rate Used for LCD TCON interface Needs no royalty / licensing fee

LVDS Interface

V-by-One HS Interface

Variable Rate (~3.75Gbps) FRC

TCON

48 lanes for FHD 240Hz

TCON

FRC

8 lanes for FHD 240Hz

4. Closer Look

TCON Interface Comparison

LVDS

iDP

V-by-One HS

First Release

1994

2010 (V1.0)

2008 (V1.0)

Current version

-

V1.0

2010 (V1.3)

Controlling Authority

ANSI/TIA/EIA-644

VESA

THine

Bit rate / pair

~ 1.12Gbps

3.24Gbps

0.6Gbps ~ 3.75Gbps

Explicit clock

Yes

No

No

No. of data ch.

4~6

1 ~ 16 lanes/bank

1,2,4,8,16,32 …

AUX channel

No

HPD

HTPDN, LOCKN

Scrambling

No

Yes

Yes

Channel coding

No

8b/10b

8b/10b

Major Application

FRC & TCON I/F

TCON I/F

TCON I/f

Lane count for FHD2401)

48

8

8

Lane count for Cinema2402)

48

93)

8

1) 1920 x 1080 resolution 2) 2560 x 1080 resolution 3) With reduced Black period or higher data rate than 3.24Gbs, this could be 8-lane.

4. Closer Look

Chip-to-Chip Interface

Mini-LVDS • Released by Texas Instrument Inc. • Internal interface between Flat Panel TCON and Column Drivers • Retains the benefits of the LVDS interface

Video Data

TCON

Row Driver

Column Driver

4. Closer Look

Chip-to-Chip Interface

Next Mini-LVDS • • • •

Point-to-Point connection between TCON and Panel High Speed up to 1.8Gbps/pair No data skew and better EMI margin Requires fewer lines than Mini-LVDS

Mini-LVDS Interface

Next Interface

(Data 6-pair & Clock 1-pair) *2 = 28 pins

TCON

Panel

FHD (10b) 120Hz

Data 6-pair = 12 pins

TCON

Panel

FHD (10b) 120Hz

4. Closer Look

Chip-to-Chip Interface

MDDI • Developed by Qualcomm & approved by VESA in 2004 • High-speed, bidirectional data transfer up to 3.2Gbps • Multiple data types simultaneously in both directions (e.g., Video, Audio, Control data, Keyboard, Pointing device)

Initial Concept at Qualcomm

2000

2001

1st Proto Development

2002

2nd Proto Development

2003

VESA MDDI SIG created

MDDI Spec. freeze

VESA MDDI WG created

MDDI becomes a VESA standard

2004

MDDI (Mobile Display Digital Interface), SIG (Special Interest Group), WG (Working Group)

4. Closer Look

Chip-to-Chip Interface

MIPI • MIPI alliance founded in 2003 by ARM, Nokia, STM, and TI • Open standard to define/promote for interfaces inside mobile devices Interface Standard CSI

MIPI Working Group (WG)

D-PHY Camera WG

PHY Layer WG

DigRF

DDB DigRFSM

DSI DPI DBI

WG

PLF WG

Display WG

SPM WG

HSI WG

Test & Debug WG

LML WG

UniProSM WG

SPMI

HSI SLIMbus

Interface Standard

System Trace Protocol Spec. Processor I/F Emulation

MIPI (Mobile Industry Processor Interface), HSI (High-speed Synchronous Interface), LML (Low-speed Multipoint Link), CML (Current Mode Logic), PLF (Peripheral and interconnect Low-level Framework), SPM (System Power Management)

4. Closer Look

Controlling Authority

PHY spec.

Data Link Count

Panel Interface Comparison

MDDI

MIPI

VESA

MIPI organization

One comprehensive spec.

Separately defined spec.

One PHY architecture : Unidirectional with reverse data flow Type 1 : 1 lane Type 2 : 2 lanes Type 3 : 4 lanes Type 4 : 8 lanes

Multiple PHY configuration : Unidirectional, Bidirectional, High speed, and Low power No link limit (4 data link recommended)

Implementation Preference

Diff. Current Mode Driver

Diff. Voltage Mode Driver

Protocol

One Protocol Document with Multiple Packet Definition

Separate Protocol Layers (Camera, Display, UniPro)

Market Focus

CDMA

GSM

Remarks

Longer Silicon History

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4. Closer Look • Box-to-Box Interface • Chip-to-Chip Interface • Memory Interface • Wireless Interface • Optical Link Interface

4. Closer Look

Memory Interface

DDR • Data Transfer on both clock edges (Rising/Falling) • Started in Graphic cards • Win against Intel’s Rambus • MDDR for mobile application

DDR2-800 DRAM

Data

I/O Prefetch

200MHz

Bus 400MHz 400MHz 800MHz

DDR3-800 DRAM

Data

I/O Prefetch

100MHz

Bus 400MHz 400MHz

DDR SDRAM

Freq. (MHz)

DDR

100 - 200

DDR2

200 - 533

DDR3

400 - 1600

800MHz

DDR3-1600 DRAM Prefetch 200MHz

Data

I/O Bus 800MHz 800MHz

1600MHz DDR (Double Data Rate), MDDR (Mobile DDR)

4. Closer Look

Memory Interface

PCIe • Computer expansion card standard, introduced in 2004, replacing the older PCI, PCI-X, and AGP PCIe

AGP

• Intel • 32-bit (Parallel) • ~2133MB/s

PCI-X

PCI

1993

• Intel/Dell/IBM/HP • 1~32-bit (Serial) • PCIe 1.0a : 250MB/s • PCIe 2.0 : 500MB/s • PCIe 3.0 : 1GB/s

• IBM/HP/Compaq • 64-bit (Parallel) • 1064MB/s

• Intel • 32/64-bit (Parallel) • 133~533MB/s 1998

2004

2010

PCIe (Peripheral Component Interconnect Express), AGP (Accelerated Graphics Port)

4. Closer Look

Memory Interface

USB • Introduced by Intel in 1996 • High-speed, easy connections of peripherals to PCs

5Gbps SuperSpeed USB 3.0 480Mbps Hi-Speed USB 2.0

Earliest version to be widely adopted

1st certified USB 3.0 product announced

USB OTG

12Mbps USB 1.1 USB 1.0

1996

1998

2000

2002

2008

2010

USB (Universal Serial Bus), OTG (On-The-Go)

4. Closer Look

Memory Interface

SATA • Computer bus interface for connecting a host bus adapter to mass storage devices, replacing PATA • Host mode and Device mode supported (“Host Swapping”) • Variants : eSATA, eSATAp Host

HDD

SATA

ODD SATA

HDD

eSATA

Port Multiplier

External HDD

HDD

SATA HDD

eSATA

Flash Memory

HDD

SATA (Serial Advanced Technology Attachment), PATA (Parallel ATA), eSATA (External SATA), eSATAp (External SATA with Power), HDD (Hard Disk Drive), ODD (Optical Disk Drive)

4. Closer Look

Comparison

DDR

USB

PCIe

SATA

First version

DDR1

USB1.0

PCIe Gen1

SATA1.0

Current version

DDR3

USB3.0

PCIe Gen3

SATA3.0

Controlling Authority

JEDEC

USB organization

-

SATA-IO

Bit rate / pair

1.6Gbps

5.0Gbps @ super speed

8.0Gbps @ Gen3

6.0Gbps @ Rev3

No. of clock ch.

1pair/8data

No

No

No

No. of data ch.

16, 32

2 pairs

4 pairs (TX) 4 pairs (RX)

1 pair (TX) 1 pair (RX)

Channel coding

No

8b/10b

128b/130b

8b/10b

Major Application

DRAM Interface

Universal

Graphic card interface @ PC

Hard Disk, SSD interface

SATA-IO (SATA International Organization)

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4. Closer Look • Box-to-Box Interface • Chip-to-Chip Interface • Memory Interface • Wireless Interface • Optical Link Interface

4. Closer Look

Wireless Interface

WirelessHD • • • • •

First 60 GHz band technology developed by SiBEAM LG announced WirelessHD TV in CES2008 4Gbps data rate (theoretically 25Gbps) in a 7GHz channel Uncompressed, lossless FHD video, audio and data transmission Smart antenna technology for non-line-of-sight (NLOS) transmission

Media Box WirelessHD TX

TV LRP signal for control

WirelessHD RX

HRP signal for A/V data

LRP (Low Rate PHY), HRP (High Rate PHY)

4. Closer Look

Wireless Interface

WiGig • Announced in 2010 by Wireless Gigabit Alliance • Operating over the unlicensed 60 GHz band • WiGig tri-band operates in the 2.4, 5 and 60 GHz bands thru liaison w/ WiFi Alliance, delivering 7Gbps data rate

WiFi (600Mbps) WiGig (7Gbps) WiGig or WiFi

WiGig & WiFi Compatibility WiGig (Wireless Gigabit Alliance)

4. Closer Look

Wireless Interface

WHDI • • • •

5 GHz band technology LG announced WHDI wireless TV in CES2010 Range of 100+ feet, through walls and obstacles 3Gbps for 1080p in a 40MHz channel or 1.5Gbps for 1080i and 720p in a 20MHz channel Wall Living room

Bed room 1 2nd Floor

Wall Bed room 2

WHDI 3Gbps Bed room 3

Kitchen

1st Floor WHDI 1.5Gbps

WHDI (Wireless Home Digital Interface)

4. Closer Look

Wireless Interface

UWB • • • •

WiMedia 1.1 and 1.5 International standards : ECMA and ISO Highest throughput, low power wireless technology for video & data 3-10GHz UWB spectrum is untapped Better battery life, Small, Low cost, & High density

Power

Existing Narrow Band Signals

UWB Frequency Band 2.4GHz

3.1GHz

5GHz

10.6GHz

UWB (Ultra-WideBand)

Freq.

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4. Closer Look • Box-to-Box Interface • Chip-to-Chip Interface • Memory Interface • Wireless Interface • Optical Link Interface

4. Closer Look

Optical Link Interface

Silicon Photonics • • • •

Fiber to the silicon chip for high speed communication Luxtera : First commercial optical cable product for 40Gbps (2009.10.) Intel : 50Gbps Silicon Photonics link with Integrated Lasers (2010.7.) ETRI : New device for 100% Ge on Silicon optical receiver (2010.7.) HDMI/DP/DIIVA ( 3~5Gbps )

Optical

Optical Cable ( 40~50Gbps )

4. Closer Look

Optical Link Interface

Silicon Photonics • • • •

Future chip : 1000 Gbps with laser-based communication (Intel) Fiber-optic cabling : large-bandwidth, long-distance, slim and small Difficulty to make optical source using only Silicon (CMOS) Poor cost competitiveness and few applications up to now Incoming electrical data stream

Hybrid Laser

Modulator

Hybrid Laser

Modulator

Hybrid Laser

Modulator

Hybrid Laser

Modulator

Connector

110100111 …

Mux

Integrated Transmitter Die

Fiber Optic Cable

Reproduced electrical data stream

Photo Det. DeMux

Photo Det.

110100111 …

Photo Det. Photo Det.

Integrated Receiver Die

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5. Conclusion

5. Conclusion

Future Trend

 As Digital TV becomes the Home Entertainment (HE) Network Hub to

interconnect and control the CE equipments, External CE Interface should build and manage the HE Network.  Current high resolution and high frame rate display will require TCONpanel interface speed to be accelerated with moderate H/W and space, getting high speed serial interface popular.  PC interface keep adopting clock-embedded serial interface

technology, realizing high speed transfer rate and compact design.

5. Conclusion

Implication & Chance

 The latest High Speed I/F standards create new market demand in the

area of Home Entertainment, Display device manufacturing, Mobile device industry, and PC industry.  Leading development and forward deployment of I/F IP is MUST for successful business, due to the tough competition between similar I/F standards and uncertainty from market dynamics.  The Gigabit Wireless Interface enables seamless interconnection

without "spaghetti wires”, and Silicon photonics can be a good candidate of next generation interface over 1Tbps.

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