1. New Product Introduction: EZ-PD CCG2: USB Type-C Cable Controller With PD CCG2 = Type-C Controller Gen2 Type-C = Reversible Slim USB Connector PD = Power Delivery
Build Your USB 3.1 Type-C Cable With CCG2, An ARM Cortex-M0-based Controller Solution in a 3.3-mm2 CSP
EZ-PD CCG2: USB Type-C Cable Controller With PD New Product Introduction
Title 1

2. Terms You Will Hear Today
USB Type-C (Type-C)
A new standard with a slimmer and reversible USB plug, a reversible cable, multiple protocol support and 100-W PD
Configuration Channel (CC)
USB Type-C bus wire used to carry the PD protocol signals
Dp, Dn
USB Type-C bus wires used to transmit and receive USB 2.0 data
TXp, TXn, RXp, RXn
USB Type-C bus wires used to transmit and receive USB 3.0 and PCIe or DisplayPort data
Sideband Use (SBU)
The use of a USB Type-C bus wire for non-USB control signals, such as DisplayPort control signals
Type-C Transceiver
A transmitter/receiver that communicates over the CC
Electronically Marked Cable Assembly (EMCA)
A USB cable with an embedded IC that reports cable characteristics (e.g., current rating) to the Type-C ports
VCONNECTOR (VCONN)
USB Type-C bus wire used to power the controller in the EMCA
VBUS
USB Type-C bus wire used for system power; usually 5 V, but increased to 20 V on 100-W USB-PD systems
USB-IF
The USB Implementers Forum creates and maintains USB specifications
USB 3.0 Type-C Plug
GND
RX2p
RX2n
VBUS Dn CC
SBU1 Dp
TX1n
TX1p
TX2p
TX2n
SBU2
VCONN
RX1n
RX1p
2.4 mm
Terms of Art 2

3. Terms You Will Hear Today
USB Power Delivery (USB-PD, PD)
A new USB standard that increases power delivery over VBUS from 7.5 W to 100 W
Both USB hosts (e.g. a PC) and USB devices (e.g. a hard disk drive) can act as either a Provider1 or a Consumer2 of power
For example, a monitor can power a notebook, which in turn can power a tablet or a hard disk drive
The USB-PD standard uses a dedicated CC wire to negotiate the Power Delivery configurations
Downstream-Facing Port (DFP), Upstream-Facing Port (UFP), Dual-Role Port (DRP)
DFP is a USB Type-C port on a host or a hub to which devices are connected
UFP is a USB Type-C port on a device or a hub that connects to a host or a hub DFP
DRP is a USB Type-C port that can operate as either a DFP or a UFP
Peripheral Component Interconnect Express (PCIe)
A standard for the primary bus in a PC
DisplayPort (DP)
A digital display interface standard developed by the Video Electronics Standards Association (VESA)
Used primarily to connect a video source to a display, such as a monitor to a PC
CCG2
A Cypress USB Type-C cable controller that complies with the latest USB Type-C and PD standards
Uses Cypress’s proprietary technology with a 32-bit, 48-MHz ARM® Cortex® -M0 processor and 32KB flash
Integrates a single Type-C Transceiver, termination resistors and system-level ESD (8-kV contact, 15-kV air)
Available in 20-ball CSP (3.3-mm2), 14-pin DFN (8.7-mm2) and 24-pin QFN (16-mm2) packages
Provides a complete, field-upgradable, one-chip, hardware and firmware solution for a USB Type-C EMCA
1 Provider: A Type-C port that sources power over VBUS 2 Consumer: A Type-C port that sinks power from VBUS
Terms of Art 3

4. USB Type-C: Connector of the Future
USB Type-A and Type-B are the current USB-IF standards, but they have limitations
They use large connectors that prevent slim industrial designs (plug height: A = 4.5 mm; B = 10.4 mm)
They require a fixed plug orientation and a fixed cable direction
They carry only USB signals
Power delivery implementation on them is complicated, expensive and limited to 7.5 W
USB Type-C is the new USB-IF standard that solves these problems and enables:
Slim industrial design with a 2.4-mm plug height
Reversible plug orientation and cable direction
Transport of both USB signals and PCIe or DisplayPort signals on the same connector
Easy implementation of low-cost power delivery up to 100 W
USB Type-C is the new, slimmer, all-in-one, 100-W connector
USB Type-C – Combines all in one
USB Micro-B
DisplayPort
Power
USB Type-B
USB Type-A
4.5 mm
10.4 mm
4.0 mm
4.7 mm
1.8 mm
2.4 mm
Market Vision 4

5. USB Type-C Cable Controllers: A $140M Market by 2019
USB Type-C cable controllers are projected to grow from $25M in 2015 to $140M+ in 2019 at a 40% CAGR
The USB Type-C port is universal: it is slimmer, reversible, handles multiple protocols and supports up to 100-W PD
USB Type-C ports communicate with the cable to determine its power rating and supported protocols
These cables must therefore be electronically marked to report their capabilities
USB Type-C cable controllers address this market with a USB-IF certified solution that:
Marks cables electronically with a controller IC embedded in the cable plug
Reports cable characteristics, including power rating and supported protocols
Multiplexes USB signals with PCIe or DisplayPort signals on the same cable
Cypress has been “Making USB Universal®” since 1996
Cypress has shipped over 1.4 billion USB controllers
Cypress has been a leading supplier in every generation of USB technology: USB 1.1, USB 2.0 and USB 3.0
Type-C cables, the emerging standard for USB 3.0, require at least one controller in each cable
EMCA Type-C Cable
A Type-C Cable with a controller on both ends of the cable
1 Electronically Marked Cable Assembly: A USB cable with an IC that reports cable characteristics (e.g., current rating) to the Type-C ports
Market Positioning 5

6. Design Problems Engineers Face
Engineers need a cost-effective USB Type-C cable solution
Dedicated controllers for EMCAs do not exist, forcing engineers to consider complex, expensive, do-it-yourself MCU solutions
MCU-based solutions do not fit inside cable assemblies
General-purpose MCUs require additional ICs and passives to implement a Type-C Transceiver
Rapidly evolving USB standards make compliance and interoperability a challenge
The USB Type-C and PD compliance test specifications are continually changing and won’t be finalized until late 2015
Cypress’s CCG2 USB Type-C cable controller solves these problems, providing:
A cost-effective, dedicated controller for the USB Type-C EMCA market
A Type-C Transceiver with integrated termination resistors and system-level ESD in a 3.3-mm2 CSP, ideal for cables
An ARM Cortex-M0 with 32KB flash and fully compliant firmware that enables field upgrades as the USB-IF specification changes
Bring your USB Type-C EMCA to market faster with CCG2, a small-footprint, reprogrammable, one-chip USB Type-C cable solution with fully compliant firmware
Design Problems 6

7. CCG2 Simplifies Design, Reduces BOM
A tiny 3.3-mm2 one-chip USB Type-C cable solution that
Fits into the smallest paddle of a USB Type-C cable
Requires only one resistor and four external capacitors to operate
CCG2 Is a Tiny, Low-Cost USB Type-C Solution for EMCA
VBUS
VCONN1
VCONN2
VCONN1
0.1μF
VCONN2
VCCD
0.1μF
1μF
XRES
VSS
4.7K
Type-C Plug
VDDD
Type-C Cable
VDDIO CC
1μF
CC1 2
D+/D-2 4
TX+/TX-, RX+/RX-3
GND
1 Configuration Channel: USB Type-C bus wire used to carry the PD protocol signals
2 USB Type-C bus wires used to transmit and receive USB 2.0 data
3 USB Type-C bus wires used to transmit and receive USB 3.0 and PCIe or DisplayPort data
Cypress Solution 7

8. CCG2 Is Programmable and Upgradable
CCG2 can be upgraded to keep pace with changes in the USB-IF specification
The ARM Cortex M0 and 32KB flash can be programmed anytime, anywhere using its Serial Wire Debug (SWD), I2C or CC1 wires
Upgrading CCG2 Using SWD
Upgrading CCG2 Using I2C
Upgrading CCG2 Using CC
Upgrade.EXE
Click Here
PSoC® Programmer
MCU
USB
I2C
CCG2
CCG2
SWD
CC1
CCG2
Run PSoC Programmer software on a PC with a MiniProg3 USB dongle to program the CCG2. Typically used during product development.
Use an MCU embedded in the USB Type-C cable/accessory or a production tester to program CCG2. Can be used on the production line or in the field.
Use a PC running a firmware upgrade application to program CCG2 in the USB Type-C cable directly. Can be deployed by cable manufacturers to provide upgrades to the end user.
1 Configuration Channel: USB Type-C bus wire used to carry the PD protocol signals
Cypress Solution 8

9. CCG2 Solution vs. Competition’s
Feature
CYPD FNXI
(DIY1 Solution)
LPC1102LVUKZ-ND
CPU
ARM CM0, 48 MHz
ARM CM0, 50 MHz
Flash2, SRAM
32KB, 4KB
32KB, 8KB
Type-C Transceiver
Yes
No; Needs external components
On-Chip Termination Resistors
System-Level ESD
±8-kV Contact, ±15-kV Air
Serial Interface
Two I2C, SPI, UART
I2C, SPI, UART
Firmware
USB-IF Compliant, field-upgradable
Information not available
Supply Voltage V V
Low Power
Deep Sleep: 2.5 μA
Deep Sleep: 1.6 μA
Package
20-ball, 3.3-mm2 CSP
25-ball, 4.5-mm2 CSP
1 Do it Yourself
2 Includes PD firmware
Competitive Comparison 9

10. CCG2 Solution Value Competitor BOM Integration Additional Value $0.80
$0.10
$0.01
$0.21
$0.16
$0.08
$0.24
$1.25
Competitor
Type C Controller: NXP LPC1102LVUK
Price: $0.801
BOM Integration
Systems Level ESD: ON Semi CM CP
Price: $0.101
Opamp: Ti LM339DR
Other Components: 7 Resistors, 1 Capacitor, 1 FET
Price: $0.011
Additional Value
USB-IF Compliant PD Protocol Stack: Saves eight man-
weeks of engineering effort at $2K per man-week,
amortized over 100,000 units
Value Added: $0.16
Integrated Type-C PHY: Saves four man-weeks of
engineering effort at $2K per man-week, amortized over
100,000 units
Value Added: $0.08
Competitor
Systems Level ESD
Opamp
Other Components
BOM Integration Value
USB-IF Compliant PD Protocol Stack
Integrated Type-C PHY
Total Additional Value
Total Value Delivered
CCG2 Solution Value new:
Total Cost:
20% Total Savings:
CYPD FNXI
$1.001
$0.25
1 Estimated 100ku pricing
Pricing 10

11. CCG2: USB Type-C Port Controller
Applications
Block Diagram
USB Type-C EMCA, Powered Accessories, UFP, DFP, DRP
CCG2: USB Type-C Cable Controller
Features
MCU Subsystem
Integrated Digital Blocks
I/O Subsystem
32-bit MCU Subsystem
48-MHz ARM® Cortex® -M0 CPU with 32KB flash and
4KB SRAM to support firmware upgrades
Integrated Digital Blocks
Integrated timers, counters and pulse-width modulators
Two SCBs1 configurable to I2C, SPI or UART modes
Type-C Support
Integrated transceiver, supporting one Type-C port
Integrated DFP (RP2), UFP (RD3), EMCA (RA4) termination resistors
Power Delivery (PD) Support
Standard power profiles
Low-Power Operation
Two independent VCONN rails with integrated isolation
Independent supply voltage pin for GPIO5
2.7-V to 5.5-V operation
Sleep: 2.0 mA; Deep Sleep: 2.5 µA
System-Level ESD on CC6 and VDD Pins
±8-kV contact, ±15-kV Air Gap IEC level 4C
Packages
20-ball, 3.3-mm2 CSP with 0.4-mm ball pitch
14-pin 2.5mm x 3.5mm DFN with 0.6mm pin pitch
24-pin 4mm x 4mm QFN with 0.55mm pin pitch
CC7
TCPWM6
VCONN1
SCB1
(I2C, SPI, UART)
Cortex-M0
48 MHz
VCONN2
SCB1
(I2C, SPI, UART)
VDDIO
GPIO5 Port
Profiles and Configurations
Advanced High-Performance Bus (AHB)
Flash (32KB)
Programmable I/O Matrix
Baseband MAC
Baseband PHY
SRAM
(4KB)
Integrated RP2, RD3, RA4
Serial Wire Debug
6 Timer, counter, pulse-width modulation block
7 Configuration Channel
Collateral
Availability
Preliminary Datasheet: CCG2 Datasheet
Samples: Now Production: June 2015
1 Serial communication block configurable as UART, SPI or I2C Termination resistor read as a UFP 5 General-purpose input/output
2 Termination resistor read as a DFP 4 Termination resistor read as an EMCA
Product Overview 11

12. Getting Started With CCG2
1. Buy the $40 CY4502 EZ-PD CCG2 Development Kit:
The kit enables simple, rapid development for USB Type-C EMCA
Includes both passive and active EMCA solutions
Provides direct access to all device GPIOs
2. Download the Hardware Design Guidelines for CCG2 App Note :
USB-PD, USB Type-C Demo Kit
3.54”
1.14”
Getting Started 12

13. APPENDIX
Appendix 13

14. References and Links
Product datasheet: CCG2 Datasheet Product roadmap: USB Roadmap CY4502 EZ-PD CCG2 Development Kit: CCG2 Development Kit Product demo video: CCG2 Demo Video App Note: Hardware Design Guidelines for CCG2 (AN95599) Knowledge Base Article: CCG2 Knowledge Base USB 3.1 specification, including Type-C: USB Power Delivery specification: Visit the CCG2 product webpage for additional details
References and Links 14

15. Type-C product applies to any USB speed
USB Portfolio
Device
Hub
Bridge
Host
Storage
Type-C
USB 3.0
CYUSB301x
FX3
32-Bit Bus to USB 3.0
ARM9, 512KB RAM
CYUSB33xx
HX3
4 Ports, Shared Link™1
BC 1.22, Ghost Charge™3
CYUSB306x
CX3
CSI-24 to USB 3.0
4 CSI-24 Lanes, 1 Gbps/Lane
CYUSB303x
FX3S
16-Bit Bus to USB 3.0
RAID5, Dual SDXC6/eMMC7
CYPD1xxx
CCG1
USB Type-C Port Controller
2 PD Ports, 5 Profiles, 100 W
DX3
USB 3.0 to DSI8 TX
Contact Sales
NEW
Q315
CYUSB302x
SD3
SDXC6/eMMC7 to USB 3.0
RAID5
NEW
CYPD2xxx
CCG2
USB Type-C Cable Controller
1 PD Port, Termination, ESD
Q215
GX3
USB 3.0 to Gigabit Ethernet
Contact Sales
NEW
Q215
CCG3
USB Type-C Port Controller
Contact Sales
NEW
Q415
USB 2.0
CY7C6801x/53
FX2LP
16-Bit Bus to USB 2.0
8051, 16KB RAM
CY7C656x4
HX2VL
4 Ports
4 Transaction Translators
CYWB016xBB
Bay™
HS USB OTG
Dual SDXC6/eMMC7
CYWB0x2xABS
Arroyo™, Astoria™
16-Bit Bus to USB 2.0
8051, Dual SD/eMMC7
CY7C68003 TX2UL
ULPI9 PHY
13, 19.2, 24, 26 MHz
CY7C656x1
HX2LP
4 Ports, Industrial Grade
1 Transaction Translator
CY7C6803x
NX2LP
NAND Flash to USB 2.0
8051, 15KB RAM
CY7C683xx AT2LP
Parallel ATA to USB 2.0
8051
Type-C product applies to any USB speed
USB 1.1
CY7C638xx enCoRe™ II
M8C MCU, 20 GPIOs
SPI, 8KB Flash
CY7C6521x
USB-Serial
UART/SPI/I2C to USB
2 Channels, CapSense®
SL811HS
FS USB Host/Device
256Byte RAM
CY7C64215 enCoRe III
M8C MCU, 50 GPIOs, ADC
I2C/SPI, 16KB Flash
CY7C65213
USB-to-UART (Gen 2)
3 Mbps, 8 GPIOs
CY7C67300 EZ-Host
4 Ports, FS USB OTG
32 GPIOs
CY7C643xx enCoRe V
M8C MCU, 36 GPIOs, ADC
I2C/SPI, 32KB Flash
CY7C64225
USB-to-UART (Gen 1)
230 Kbps
CY7C67200 EZ-OTG™
2 Ports, FS USB OTG
25 GPIOs
1 Simultaneous USB 2.0 and USB 3.0 traffic on the same port
2 Battery Charging specification v1.2
3 Enables USB charging without host connection
4 Camera Serial Interface v2.0
5 Redundant array of independent disks
6 SD extended capacity
7 Embedded MultiMedia Card
8 Display Serial Interface
9 UTMI low-pin interface
Production
Development
QQYY
Availability
Sampling
Concept
Status
Roadmap 15

16. Passive EMCA1 With Two CCG2
CCG2 Solution Example:
Passive EMCA1 With Two CCG2
Cypress Solution Value
Block Diagram
Design Challenges
Type-C cables will start converting to EMCA by mid-2015
EMCA must support the Power Delivery (PD7) protocol
Cable solutions must be turnkey for ease of design
Solutions must be reprogrammable to keep up with USB-IF standards
A high level of integration is required to reduce the BOM
Solutions must be in a package that fits in a cable assembly
CCG2 Solution
Supports Type-C EMCA with an ARM® Cortex®-M0 controller
Supports PD protocol for EMCA with 32KB flash
Ships with USB-IF certified factory-programmed firmware
Supports field upgrades with free, fully compliant firmware
Integrates transceiver, termination resistors and system ESD
Available in 3.3-mm2 CSP and 8.7mm2 DFN packages
Passive EMCA1 With One CCG2 Per Cable Plug
VBUS4 2
Data Lines (USB SuperSpeed, USB Hi-Speed, PCIe2, DisplayPort3) 12
CC5
VCONN6
VCONN6
Type-C Plug
Type-C Plug
CCG2
CYPD FNXI
CCG2
CYPD FNXI
Secure
EEPROM 2 2
Secure
EEPROM
I2C
I2C
GND 2
Webpage: CCG2 Web page
Datasheet: CCG2 Datasheet
App Note: Getting Started with CCG2
Demo Kit: CCG2 EMCA Development Kit
Suggested Collateral
Passive EMCA1 with CCG2
An EMCA1 that supports the PD protocol. A CCG2 is embedded at each end of the cable and is powered individually by the USB Type-C port at each end.
Get a CCG2 EMCA Development Kit
How To Get Started
1 Electronically Marked Cable Assembly without a re-driver 4 The power wire inside a USB cable
2 Peripheral Component Interconnect Express is an interface standard for connecting peripherals 5 Configuration Channel
3 A display interface standard developed by the Video Electronics Standards 6 USB Type-C bus wire used to power the IC in the EMCA
Association used primarily to connect a video source to a display such as a computer monitor 7 A new USB standard that increases power delivery over VBUS from 7.5 W to 100 W
Solution Example 16

17. Passive EMCA1 With One CCG2
CCG2 Solution Example:
Passive EMCA1 With One CCG2
Cypress Solution Value
Block Diagram
Design Challenges
Type-C cables will start converting to EMCA by mid-2015
EMCA must support the Power Delivery (PD7) protocol
Cable solutions must be turnkey for ease of design
Solutions must be reprogrammable to keep up with USB-IF standards
A high level of integration is required to reduce the BOM
Solutions must be in a package that fits in a cable assembly
CCG2 Solution
Supports Type-C EMCA with an ARM® Cortex® -M0 controller
Supports PD protocol for EMCA with 32KB flash
Ships with USB-IF certified factory-programmed firmware
Supports field upgrades with free, fully compliant firmware
Integrates transceiver, termination resistors and system ESD
Available in 3.3-mm2 CSP and 8.7mm2 DFN packages
Passive EMCA1 With One CCG2 Per Cable
VBUS4 2
Data Lines (USB SuperSpeed, USB Hi-Speed, PCIe2, DisplayPort3) 12
CC5
VCONN6 Near
VCONN6 Far
Type-C Plug
Type-C Plug
CCG2
CYPD FNXI
Secure
EEPROM 2
I2C
GND 2
Suggested Collateral
Webpage: CCG2 Web page
Datasheet: CCG2 Datasheet
App Note: Getting Started with CCG2
Video: CCG2 Demo Video
Demo Kit: CCG2 EMCA Development Kit
Passive EMCA1 with CCG2
A lower-cost implementation of EMCA1 that supports the PD protocol. A CCG2 is embedded at only one end of the cable and is powered by either USB Type-C port at each end.
How To Get Started
Get a CCG2 EMCA Development Kit
1 Electronically Marked Cable Assembly without a re-driver 4 The power wire inside a USB cable
2 Peripheral Component Interconnect Express is an interface standard for connecting peripherals 5 Configuration Channel
3 A display interface standard developed by the Video Electronics Standards 6 USB Type-C bus wire used to power the IC in the EMCA
Association used primarily to connect a video source to a display such as a computer monitor 7 A new USB standard that increases power delivery over VBUS from 7.5 W to 100 W
Solution Example 17

18. Active EMCA1 CCG2 Solution Example: Cypress Solution Value
Block Diagram
Design Challenges
Type-C cables will start converting to EMCA by mid-2015
EMCA must support the Power Delivery (PD7) protocol
Cable solutions must be turnkey for ease of design
Solutions must be reprogrammable to keep up with USB-IF standards
A high level of integration is required to reduce the BOM
Solutions must be in a package that fits in a cable assembly
CCG2 Solution
Supports Type-C EMCA with an ARM® Cortex® -M0 controller
Supports PD protocol for EMCA with 32KB flash
Ships with USB-IF certified factory-programmed firmware
Supports field upgrades with free, fully compliant firmware
Integrates transceiver, termination resistors and system ESD
Available in a 3.3-mm2 CSP
Active EMCA1
VBUS4 2
Data Lines (USB SuperSpeed, USB Hi-Speed, PCIe2, DisplayPort3) 12 12
Re-driver
CCG2
CYPD FNXI
Secure
EEPROM 2 2
Type-C Plug
I2C
GPIOs
Type-C Cable
VCONN6 Near
VCONN6 Far
CC5
GND 2
Suggested Collateral
Webpage: CCG2 Web page
Datasheet: CCG2 Datasheet
App Note: Getting Started with CCG2
Video: CCG2 Demo Video
Demo Kit: CCG2 EMCA Development Kit
Active EMCA1 with CCG2
An EMCA1 that includes an embedded re-driver to extend the cable length.
How To Get Started
Get a CCG2 EMCA Development Kit
1 Electronically Marked Cable Assembly with a re-driver 4 The power wire inside a USB cable
2 Peripheral Component Interconnect Express is an interface standard for connecting peripherals 5 Configuration Channel
3 A display interface standard developed by the Video Electronics Standards 6 USB Type-C bus wire used to power the IC in the EMCA
Association used primarily to connect a video source to a display such as a computer monitor 7 A new USB standard that increases power delivery over VBUS from 7.5 W to 100 W
Solution Example 18

19. USB Type-C to HDMI1 Dongle Solution
CCG2 Solution Example:
USB Type-C to HDMI1 Dongle Solution
Cypress Solution Value
Block Diagram
Design Challenges
Legacy displays have HDMI1 and not Type-C
Solutions must be turnkey for ease of design
Solutions must be reprogrammable to keep up with USB-IF standards
Solutions must be highly integrated to lower BOM cost
Solutions must be in a package that fits in a cable assembly
CCG2 Solution
Supports Type-C to HDMI1 with an ARM® Cortex®-M0 controller and 32KB flash
Ships with USB-IF compliant factory-programmed firmware
Supports field upgrades with free, fully compliant firmware
Integrates Type-C transceiver, supports multiple protocols
Available in a 3.3-mm2 CSP
USB Type-C HDMI Dongle
Data Lines (USB SuperSpeed, USB Hi-Speed, DisplayPort2) 12 10
DisplayPort2
to HMDI1
Bridge
USB Hi-Speed 2 8
CCG2
CYPD FNXI
Secure
EEPROM 2 2
USB
Device
Controller 2
HDMI1
Type-C Plug
I2C
GPIOs
HDMI1 Plug
I2C
VCONN4
CC3
GND 2
Suggested Collateral
Webpage: CCG2 Web page
Datasheet: CCG2 Datasheet
App Note: Getting Started with CCG2
Video: CCG2 Demo Video
Demo Kit: CCG2 EMCA Development Kit
USB Type-C HDMI Dongle
A notebook PC accessory that converts a USB Type-C port to an HDMI output to connect a monitor.
How To Get Started
Get a CCG2 EMCA Development Kit
1 High Definition Multimedia Interface Configuration Channel
2 A display interface standard developed by the Video Electronics Standards Association 4 USB Type-C bus wire used to power the IC in the EMCA
used primarily to connect a video source to a display such as a computer monitor
Solution Example 19

20. AC Adapter Primary Side AC to DC Power Conversion
CCG2 Solution Example:
Type-C Power Adapter
Cypress Solution Value
Block Diagram
Design Challenges
Power Adapter designers want a Type-C solution now
Short time-to-market demands programmable solutions
Solutions must be turnkey for ease of design
Solutions must be highly integrated to lower BOM cost
Solutions must be reprogrammable to keep up with USB-IF standards
Industry standards demand low power for no-load conditions
CCG2 Solution
Provides Type-C solution with Power Delivery (PD1) today
Includes an ARM® Cortex®-M0 with 32KB flash
Ships with USB-IF compliant factory-programmed firmware
Integrates Type-C Transceiver, termination resistors and system ESD protection
Supports field upgrades with free, fully compliant firmware
Delivers low power: Deep Sleep 2.5 µA
Type-C Power Adapter with CCG2
AC Adapter Primary Side AC to DC Power Conversion
USB
Type-C
Captive Cable
Assembly9
VOUT2
FET
VBUS3
20-V to 3.3-V
Regulator
Gate
Driver
FET
VDD
VBUS_CTRL5
VBUS_DIS6
VBUS_MON8
CCG2
CYPD LQXI
VSEL4
CC7
GND
Suggested Collateral
Webpage: CCG2 Web page
Datasheet: CCG2 Datasheet
Video: CCG2 Demo Video
Type-C Power Adapter with CCG2
CCG2 supports all PD Profiles required for a 100-W power adapter
How To Get Started
Contact Sales for CCG2 Client Development board
1 A new USB standard that increases power delivery over VBUS from 7.5 W to 100 W 6 Signal to control VBUS discharge FET
2 DC output voltage of the AC adapter 7 Configuration Channel is the USB Type-C bus wire used to carry the PD protocol signals
3 The power wire of the USB bus 8 VBUS monitoring node for Over-Voltage and Under-voltage protection
4 Output voltage selection 9 A cable permanently attached to the AC adapter
5 Signal to control VBUS load
Solution Example 20

21. Type-C Notebook CCG2 Solution Example: Cypress Solution Value
Block Diagram
Design Challenges
Notebook designers want a Type-C solution now
Short time-to-market demands programmable solutions
Solutions must be turnkey for ease of design
Solutions must be highly integrated to lower BOM cost
Solutions must be reprogrammable to keep up with USB-IF standards
Video, data and power use multiple types of connectors
CCG2 Solution
Provides Type-C solution with Power Delivery (PD1) today
Includes an ARM® Cortex®-M0 with 32KB flash
Ships with USB-IF compliant factory-programmed firmware
Integrates Type-C Transceiver, termination resistors and system ESD protection
Supports field upgrades with free, fully compliant firmware
Routes video, data and power over one Type-C connector
Type-C Notebook with CCG2
VCONN7
VCONN Supply
2 FETs
USB
Type-C Receptacle
VBUS4
BCC2
Battery
Gate
Driver
2 FETs
VCONN_CTRL10
VBUS_MON9
I2C 2 3
VBUS_CTRL6
FET_CTRL5
CCG2
CYPD LQXI
CC8
EC3 3
I2C 2
USB Host on
Motherboard 6
MUX 10
Data Lines
DisplayPort on
Motherboard 8
Suggested Collateral
Webpage: CCG2 Web page
Datasheet: CCG2 Datasheet
Video: CCG2 Demo Video
Type-C Notebook with CCG2
CCG2 supports both PD provider and consumer roles, allowing a notebook to provide power to or consume power from its Type-C port
How To Get Started
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1 A new USB standard that increases power delivery over VBUS from 7.5 W to 100 W 7 The power wire of the USB Type-C bus that is used to power the IC in the EMCA. An
2 Battery charge controller Electronically Marked Cable Assembly (EMCA ) is a USB cable with an IC that reports
3 Embedded controller is the keyboard controller, often used as a general-purpose MCU cable characteristics (e.g., current rating) to the Type-C ports
4 The power wire of the USB bus 8 Configuration Channel is the USB Type-C bus wire used to carry the PD protocol signals
5 Signals to control VBUS and VCONN switch FETs 9 VBUS monitoring node for Over-Voltage and Under-voltage protection
6 Signal to control the provide and consumer VBUS load 10 VCONN control signal to turn on VCONN
Solution Example 21

22. CCG2 Product Selector Guide
Part Number
Application
Type-C Ports
OCP
OVP
Termination
Resistor
Role
Package
CYPD FNXIT
Passive EMCA1 1 No
RA4
Cable
20-CSP
CYPD LHXIT
14-DFN
CYPD FNXIT
Active EMCA2
CYPD FNXIT
Accessory3
RA4, Rd5
UFP
CYPD FNXIT
Tablet
RP6, Rd5
DRP
CYPD LQXIT
Notebook
24-QFN
CYPD LQXIT
DFP
RP6
CYPD LQXIT
Part Numbering Decoder CY PD X X X X - XX XX X I
Temperature Range: I = Industrial
Lead: X = Lead-free
Package Type: LQ = QFN, FN = CSP, PV = SSOP, LH = DFN
Number of pins in the package
System Use: Unique combination of role and termination4,5
Feature: Unique combination of OCP, OVP
(0 = No, No; 1 = Yes, No; 2 = No, Yes; 3 = Yes, Yes)
Number of Type-C ports: 1 = 1 Port, 2 = 2 Port
Product Type: 1 = First generation, 2 = Second generation
Marketing Code: PD = Power Delivery product family
Company ID: CY = Cypress
1 Electronically Marked Cable Assembly without a re-driver 4 Termination resistor denoting an EMCA
2 Electronically Marked Cable Assembly with a re-driver Termination resistor denoting an UFP or Accessory
3 A dongle for bridging Type-C to Type-A, Type-B, Display Port, HDMI or Thunderbolt 6 Termination resistor denoting a DFP
Product Selector Guide 22