Cypress CYPD3120-40LQXI Usb type-c port controller Datasheet

EZ-PD™ CCG3
USB Type-C Port Controller
General Description
EZ-PD™ CCG3 is a highly integrated USB Type-C controller that complies with the latest USB Type-C and PD standards. EZ-PD
CCG3 provides a complete USB Type-C and USB-Power Delivery port control solution for notebooks, dongles, monitors, docking
stations and power adapters. CCG3 uses Cypress’s proprietary M0S8 technology with a 32-bit, 48-MHz ARM® Cortex® -M0 processor
with 128-KB flash, 8-KB SRAM, 20 GPIOs, full-speed USB device controller, a Crypto engine for authentication, a 20V-tolerant
regulator, and a pair of FETs to switch a 5V (VCONN) supply, which powers cables. CCG3 also integrates two pairs of gate drivers to
control external VBUS FETs and system level ESD protection. CCG3 is available in 40-QFN, 32-QFN, and 42-WLCSP packages.
Features
Clocks and Oscillators
■
Type-C and USB-PD Support
Integrated oscillator eliminating the need for external clock
■
Integrated USB Power Delivery 3.0 support
Integrated USB-PD BMC transceiver
■ Integrated VCONN FETs
■ Configurable resistors RA, RP, and RD
■ Dead Battery Detection support
■ Integrated fast role swap and extended data messaging
■ Supports one USB Type-C port
■ Integrated Hardware based overcurrent protection (OCP) and
overvoltage protection (OVP)
Power
■
■
2.7 V to 21.5 V operation
■
2x Integrated dual-output gate drivers for external VBUS FET
switch control
■
Independent supply voltage pin for GPIO that allows 1.71 V to
5.5 V signaling on the I/Os
■
Reset: 30 µA, Deep Sleep: 30 µA, Sleep: 3.5 mA
32-bit MCU Subsystem
■
■
48-MHz ARM Cortex-M0 CPU
128-KB Flash
■ 8-KB SRAM
■
■
On CC, SBU, DPLUS, DMINUS and VBUS pins
± 8-kV Contact Discharge and ±15-kV Air Gap Discharge based
on IEC61000-4-2 level 4C
Packages
Integrated Digital Blocks
Hardware Crypto block enables Authentication
Full-Speed USB Device Controller supporting Billboard Device
Class
■ Integrated timers and counters to meet response times
required by the USB-PD protocol
■ Four run-time reconfigurable serial communication blocks
(SCBs) with reconfigurable I2C, SPI, or UART functionality
■
■
Cypress Semiconductor Corporation
Document Number: 002-03288 Rev. *J
System-Level ESD Protection
•
■
40-pin QFN, 32-pin QFN, and 42-ball CSP for
Notebooks/Accessories
■
Supports industrial temperature range (–40 °C to +105 °C)
198 Champion Court
•
San Jose, CA 95134-1709
•
408-943-2600
Revised February 23, 2018
EZ-PD™ CCG3
Logic Block Diagram
Document Number: 002-03288 Rev. *J
Page 2 of 45
EZ-PD™ CCG3
Contents
EZ-PD CCG3 Block Diagram ............................................ 4
Functional Overview ........................................................ 5
CPU and Memory Subsystem ..................................... 5
Crypto Block ................................................................ 5
Integrated Billboard Device ......................................... 5
USB-PD Subsystem (USBPD SS) .............................. 5
Full-Speed USB Subsystem ........................................ 6
Peripherals .................................................................. 6
GPIO ........................................................................... 7
Power Systems Overview ................................................ 8
Pinouts .............................................................................. 9
Available Firmware and Software Tools ....................... 13
EZ-PD Configuration Utility ....................................... 13
CCG3 Programming and Bootloading .......................... 14
Programming the Device Flash over SWD
Interface ..................................................................... 14
Application Firmware Update over Specific
Interfaces (I2C, CC, USB) ......................................... 14
Applications .................................................................... 17
Document Number: 002-03288 Rev. *J
Electrical Specifications ................................................ 23
Absolute Maximum Ratings ....................................... 23
Device-Level Specifications ...................................... 24
Digital Peripherals ..................................................... 26
System Resources .................................................... 28
Ordering Information ...................................................... 34
Ordering Code Definitions ......................................... 34
Packaging ........................................................................ 35
Acronyms ........................................................................ 38
Document Conventions ................................................. 39
Units of Measure ....................................................... 39
References and Links to Applications Collaterals ..... 40
Document History Page ................................................. 41
Sales, Solutions, and Legal Information ...................... 45
Worldwide Sales and Design Support ....................... 45
Products .................................................................... 45
PSoC® Solutions ...................................................... 45
Cypress Developer Community ................................. 45
Technical Support ..................................................... 45
Page 3 of 45
EZ-PD™ CCG3
EZ-PD CCG3 Block Diagram
Figure 1. EZ-PD CCG3 Block Diagram[1]
CPU Subsystem
FLASH
2x64 KB
SRAM
8 KB
ROM
8 KB
FAST MUL
NVIC, IRQMX
Read Accelerator
SRAM Controller
ROM Controller
System Resources
Lite
Power Modes
Active/Sleep
Deep Sleep
High Speed I/O Matrix
ADC / ACA
CHG DET
Pads, ESD
USB-FS
CC BB PHY
2 X VCONN FET
OCP
2 X GATE DRIVER
USB-PD SS
2 x 2 ANALOG XBAR
Test
DFT Logic
DFT Analog
Peripheral Interconnect (MMIO)
PCLK
OVP
Reset
Reset Control
XRES
Peripherals
4 x TCPWM
Clock
Clock Control
WDT
IMO
ILO
System Interconnect (Single Layer AHB)
IOSS GPIO (3 x ports)
Power
Sleep Control
WIC
POR
REF
PWRSYS
HV REG
AHB-Lite
SPCIF
CRYPTO
32-bit
SWD/TC
Cortex
M0
48 MHz
4 x SCB
CCG3
FS-PHY
22 x GPIOs, 2 x OVTs
I/O Subsystem
Note
1. See Acronyms section for more details.
Document Number: 002-03288 Rev. *J
Page 4 of 45
EZ-PD™ CCG3
Functional Overview
CPU and Memory Subsystem
USB-PD Subsystem (USBPD SS)
CPU
The USB-PD subsystem contains all of the blocks related to USB
Type-C and Power Delivery. The subsystem consists of the
following:
The Cortex-M0 CPU in EZ-PD CCG3 is part of the 32-bit MCU
subsystem, which is optimized for low-power operation with
extensive clock gating. It mostly uses 16-bit instructions and
executes a subset of the Thumb-2 instruction set. This enables
fully compatible binary upward migration of the code to higher
performance processors such as the Cortex-M3 and M4, thus
enabling upward compatibility. The Cypress implementation
includes a hardware multiplier that provides a 32-bit result in one
cycle. It includes a nested vectored interrupt controller (NVIC)
block with 32 interrupt inputs and also includes a Wakeup
Interrupt Controller (WIC). The WIC can wake the processor up
from the Deep Sleep mode, allowing power to be switched off to
the main processor when the chip is in the Deep Sleep mode.
The Cortex-M0 CPU provides a Non-Maskable Interrupt (NMI)
input, which is made available to the user when it is not in use
for system functions requested by the user.
The CPU also includes a serial wire debug (SWD) interface,
which is a two-wire form of JTAG. The debug configuration used
for EZ-PD CCG3 has four break-point (address) comparators
and two watchpoint (data) comparators.
Flash
The EZ-PD CCG3 device has a flash module with two banks of
64 KB flash, a flash accelerator, tightly coupled to the CPU to
improve average access times from the flash block. The flash
block is designed to deliver 1 wait-state (WS) access time at
48 MHz and with 0-WS access time at 24 MHz. The flash
accelerator delivers 85% of single-cycle SRAM access
performance on average. Part of the flash module can be used
to emulate EEPROM operation if required.
SROM
A supervisory ROM that contains boot and configuration routines
is provided.
Crypto Block
CCG3 integrates a crypto block for hardware assisted
authentication of firmware images. It also supports field
upgradeability of firmware in a trusted ecosystem. The CCG3
Crypto block provides cryptography functionality. It includes
hardware acceleration blocks for Advanced Encryption Standard
(AES) block cipher, Secure Hash Algorithm (SHA-1 and SHA-2),
Cyclic Redundancy Check (CRC), and pseudo random number
generation.
Integrated Billboard Device
CCG3 integrates a complete full speed USB 2.0 device controller
capable of functioning as a Billboard class device. The USB 2.0
device controller can also support other device classes.
Document Number: 002-03288 Rev. *J
■
Biphase Marked Coding (BMC) PHY: USB-PD Transceiver with
Fast Role Swap (FRS) transmit and detect
■
VCONN power FETs for the CC lines
■
VCONN RA Termination and Leakers
■
Analog Crossbar to switch between the SBU1/SBU2 and
AUX_P/AUX_N pins
■
Programmable pull-up and pull-down termination on the
AUX_P/AUX_N pins
■
Hot Plug Detect (HPD) processor
■
VBUS_C regulator (20V LDO)
■
Power switch between VSYS supply and VBUS_C regulator
output
■
VBUS_C overvoltage (OV) and undervoltage (UV) detectors
■
Current sense amplifier (CSA) for overcurrent detection
■
Gate Drivers for VBUS_P and VBUS_C external Power FETs
■
VBUS_C discharge switch
■
USB2.0 Full-Speed (FS) PHY with integrated 5.0 V to 3.3 V
regulator
■
Charger Detection/Emulation for USB BC1.2 and other
proprietary protocols
■
Two instances of 8-bit SAR ADCs
■
8-kV IEC ESD Protection on the following pins: VBUS_C, CC1,
CC2, SBU1, SBU2, DP, DM
The EZ-PD CCG3 USB-PD subsystem interfaces to the pins of
a USB Type-C connector. It includes a USB Type-C baseband
transceiver and physical-layer logic. This transceiver performs
the BMC and the 4b/5b encoding and decoding functions as well
as integrating the 1.2-V analog front end (AFE). This subsystem
integrates the required terminations to identify the role of the
CCG3 device, including RP and RD for UFP/DFP roles and RA
for EMCA/VCONN powered accessories. The programmable
VCONN leakers are included to discharge VCONN capacitance
during a disconnect event. It also integrates power FETs for
supplying VCONN power to the CC1/CC2 pins from the V5V pin.
The analog crossbar enables connecting either of the
SBU1/SBU2 pins to either of the AUX_P/AUX_N pins to support
DisplayPort sideband signaling. The integrated HPD processor
can be used to control or monitor the HPD signal of a DisplayPort
source or sink.
Page 5 of 45
EZ-PD™ CCG3
The Overvoltage/Undervoltage (OV/UV) block monitors the
VBUS_C supply for programmable overvoltage and
undervoltage conditions. The CSA amplifies the voltage across
an external sense resistor, which is proportional to the current
being drawn from the external DC-DC VBUS supply converter.
The CSA output can either be measured with an ADC or
configured to detect an overcurrent condition. The VBUS_P and
VBUS_C gate drivers control the gates of external power FETs
for the VBUS_C and VBUS_P supplies. The gate drivers can be
configured to support both P and N type external power FETs.
The gate drivers are configured by default for nFET devices. In
applications using pFETs, the gate drivers must be appropriately
configured. The OV/UV and CSA blocks can generate interrupts
to automatically turn off the power FETs for the programmed
overvoltage and overcurrent conditions. The VBUS_C discharge
switch allows for discharging the VBUS_C line through an
external resistor.
The USB-PD subsystem also contains two 8-bit Successive
Approximation Register (SAR) ADCs for analog to digital
conversions. The voltage reference for the ADCs is generated
from the VDDD supply. Each ADC includes an 8-bit DAC and a
comparator. The DAC output forms the positive input of the
comparator. The negative input of the comparator is from a
4-input multiplexer. The four inputs of the multiplexer are a pair
of global analog multiplex busses, an internal bandgap voltage
and an internal voltage proportional to the absolute temperature.
Each GPIO pin can be connected to the global Analog Multiplex
Busses through a switch, which allows either ADC to sample the
pin voltage. When sensing the GPIO pin voltage with an ADC,
the pin voltage cannot exceed the VDDIO supply value.
Figure 2. USB-PD Subsystem
CONSUMER N/PFETs
charger
PRODUCER N/PFETs
dc-dc
VBUS_P
OC
VBUS_P_CTRL
Gate
Driver
CSA
VBUS_C_CTRL
Gate
Driver
VBUS_DISCHARGE
VDDD
VSYS
POWER
SWITCH
RA
VBUS_C
OV/UV
VCONN
SWITCH
Leaker
CC1
V5V
CC2
PROGRAMMABLE
PULL-UP, PULL-DOWN
BMC
PHY w/ FRS
AUX_P
SBU1
ANALOG
CROSS-BAR
AUX_N
HPD
SBU2
USB Type-C Port
VCONN
LDO
DP
HPD
2x
ADCs
USB 2.0
FS PHY
CHARGER
DETECT
DM
USB PD SubSystem
Full-Speed USB Subsystem
The FSUSB subsystem contains a full-speed USB device
controller as described in the Integrated Billboard Device
section.
Peripherals
Serial Communication Blocks (SCB)
EZ-PD CCG3 has four SCBs, which can be configured to
implement an I2C, SPI, or UART interface. The hardware I2C
blocks implement full multi-master and slave interfaces capable
of multimaster arbitration. In the SPI mode, the SCB blocks can
be configured to act as master or slave.
In the I2C mode, the SCB blocks are capable of operating at
speeds of up to 1 Mbps (Fast Mode Plus) and have flexible
buffering options to reduce interrupt overhead and latency for the
CPU. These blocks also support I2C that creates a mailbox
address range in the memory of EZ-PD CCG3 and effectively
reduce I2C communication to reading from and writing to an
array in memory. In addition, the blocks support 8-deep FIFOs
for receive and transmit which, by increasing the time given for
the CPU to read data, greatly reduce the need for clock
stretching caused by the CPU not having read data on time.
The I2C peripherals are compatible with the I2C Standard-mode,
Fast-mode, and Fast-mode Plus devices as defined in the NXP
I2C-bus specification and user manual (UM10204).
The I2C bus I/Os are implemented with GPIO in open-drain
modes.
Document Number: 002-03288 Rev. *J
Page 6 of 45
EZ-PD™ CCG3
The I2C port on SCB 1-3 blocks of EZ-PD CCG3 are not
completely compliant with the I2C specification in the following
aspects:
■
The GPIO cells for SCB 1's I2C port are not overvoltage-tolerant
and, therefore, cannot be hot-swapped or powered up
independently of the rest of the I2C system.
■
Fast-mode Plus has an IOL specification of 20 mA at a VOL of
0.4 V. The GPIO cells can sink a maximum of 8-mA IOL with a
VOL maximum of 0.6 V.
■
Fast-mode and Fast-mode Plus specify minimum Fall times,
which are not met with the GPIO cell; Slow strong mode can
help meet this spec depending on the bus load.
Timer/Counter/PWM Block (TCPWM)
EZ-PD CCG3 has four TCPWM blocks. Each implements a
16-bit timer, counter, pulse-width modulator (PWM), and
quadrature decoder functionality.
GPIO
EZ-PD CCG3 has up to 20 GPIOs (these GPIOs can be
configured for GPIOs, SCB, SBU, and Aux signals) and SWD
pins, which can also be used as GPIOs. The I2C pins from SCB
0 are overvoltage-tolerant.
The GPIO block implements the following:
■
Seven drive strength modes:
❐ Input only
❐ Weak pull-up with strong pull-down
❐ Strong pull-up with weak pull-down
❐ Open drain with strong pull-down
❐ Open drain with strong pull-up
❐ Strong pull-up with strong pull-down
❐ Weak pull-up with weak pull-down
■
Input threshold select (CMOS or LVTTL)
■
Individual control of input and output buffer enabling/disabling
in addition to the drive strength modes
■
Hold mode for latching previous state (used for retaining I/O
state in Deep Sleep mode)
■
Selectable slew rates for dV/dt related noise control to improve
EMI
During power-on and reset, the I/O pins are forced to the disable
state so as not to crowbar any inputs and/or cause excess
turn-on current. A multiplexing network known as a high-speed
I/O matrix is used to multiplex between various signals that may
connect to an I/O pin.
Document Number: 002-03288 Rev. *J
Page 7 of 45
EZ-PD™ CCG3
Power Systems Overview
Figure 3 shows an overview of the CCG3 power system
requirement. CCG3 shall be able to operate from two possible
external supply sources VBUS (4.0 V–21.5 V) or VSYS (2.7 V–
5.5 V). The VBUS supply is regulated inside the chip with a
low-dropout regulator (LDO) down to 3.3-V level. The chip’s
internal VDDD rail is intelligently switched between the output of
the VBUS regulator and unregulated VSYS. The switched
supply, VDDD is either used directly inside some analog blocks
or further regulated down to VCCD which powers majority of the
core using regulators. Besides Reset mode, CCG3 has three
different power modes: Active, Sleep and Deep Sleep,
transitions between which are managed by the Power System.
A separate power domain VDDIO is provided for the GPIOs. The
VDDD and VCCD pins, both the output of regulators are brought
out for connecting a 1-µF capacitor for the regulator stability only.
These pins are not supported as power supplies. When CCG3 is
powered from VSYS that is greater than 3.3 V, the dedicated
USB regulator allows USB operation.
Figure 3. EZ-PD CCG3 Power System Block Diagram
VSYS
1uF
Switch
VBUS
LDO
VBUS_P
OC
VBUS_P_CTRL
VCONN
VBUS_DISCHARGE
OVP
OCP
RA
VDDIO
VSS
VBUS_C_CTRL
USB Regulator
Regulator
GPIO
Gate Driver
VDDD
Gate Driver
VCCD
1uF
1uF
Core
FS-USB
TX/RX
CC
Tx/Rx
1uF
DP, DM
CC1, CC2
VSS
CCG3
Table 1. CCG3 Power Modes
Mode
Description
RESET
Power is Valid and XRES is not asserted. An internal reset source is asserted or SleepController
is sequencing the system out of reset.
ACTIVE
Power is Valid and CPU is executing instructions.
SLEEP
Power is Valid and CPU is not executing instructions. All logic that is not operating is clock gated
to save power.
DEEP SLEEP
Main regulator and most hard-IP are shut off. Deep Sleep regulator powers logic, but only
low-frequency clock is available.
Document Number: 002-03288 Rev. *J
Page 8 of 45
EZ-PD™ CCG3
Pinouts
Table 2. CCG3 Pin Description for 42-CSP, 32-QFN, and 40-QFN Devices
Pin Map
42-CSP
Pin Map
32-QFN
Pin Map
40-QFN
Name
A5
1
1
VBUS_P_CTRL1
VBUS Gate Driver Control 1 for Producer Switch
A6
1
2
VBUS_P_CTRL0
VBUS Gate Driver Control 0 for Producer Switch
B6
2
3
CC2
USB PD connector detect/Configuration Channel 2
C5
N/A
N/A
CC2
USB PD connector detect/Configuration Channel 2
D4
3
4
V5V
Input Supply Voltage for VCONN FETs
V5V = 5.0V – 5.5V to supply VCONN > 4.75V @ 1.5W
V5V = 3.5V – 5.5V to supply VCONN > 3.00V @ 1W
C6
4
5
CC1
USB PD connector detect/Configuration Channel 1
D6
N/A
N/A
CC1
USB PD connector detect/Configuration Channel 1
E6
N/A
6
VCONN
F6
5
7
P1.0
D5
N/A
8
P1.1
GPIO/UART_2_RX / SPI_2_SEL
Description
VCONN Input - provides RA termination for cable
applications
GPIO/UART_2_TX / SPI_2_MISO
E5
6
9
P1.2
GPIO/UART_0_RX/ UART_3_CTS/ SPI_3_MOSI/
I2C_3_SCL
G6
7
10
P1.3
GPIO/UART_0_TX/ UART_3_RTS/ SPI_3_CLK/
I2C_3_SDA
E4
N/A
11
AUX_P / P1.6
DisplayPort AUX_P signal / GPIO / UART_1_TX /
SPI_1_MISO
F5
8
12
SBU1 / P1.4
USB Type-C SBU1 signal / GPIO / UART_3_TX/
SPI_3_MISO/ SWD_1_CLK
G5
9
13
SBU2 / P1.5
USB Type-C SBU2 signal / GPIO / UART_3_RX/
SPI_3_SEL/ SWD_1_DAT
G4
N/A
14
AUX_N / P1.7
DisplayPort AUX_N signal / GPIO / UART_1_RX /
SPI_1_SEL
F4
10
15
P2.0
GPIO / UART_1_CTS / SPI_1_CLK/ I2C_1_SCL /
SWD_0_DAT
G3
11
16
P2.1
GPIO / UART_1_RTS / SPI_1_MOSI/ I2C_1_SDA /
SWD_0_CLK
G2
13
17
VDDD
VDDD supply Input / Output (2.7 V–5.5 V)
F3
14
18
VDDIO
1.71 V–5.5 V supply for I/Os. This supply also powers the
global analog multiplex buses.
F2
15
19
VCCD
1.8-V regulator output for filter capacitor
G1
16
20
VSYS
System power supply (2.7 V–5.5 V)
F1
17
21
DPLUS
USB 2.0 DP
USB 2.0 DM
E1
18
22
DMINUS
E2
19
23
P2.4
GPIO
D3
20
24
P2.5
GPIO / UART_0_TX/ SPI_0_MOSI
D2
N/A
25
P2.6
GPIO / UART_0_RX/ SPI_0_CLK
D1
21
26
XRES
C3
22
27
Document Number: 002-03288 Rev. *J
P0.0
External Reset Input. Internally pulled-up to VDDIO.
I2C_0_SDA / GPIO_OVT / UART_0_CTS / SPI_0_SEL/
TCPWM0
Page 9 of 45
EZ-PD™ CCG3
Table 2. CCG3 Pin Description for 42-CSP, 32-QFN, and 40-QFN Devices (continued)
Pin Map
42-CSP
Pin Map
32-QFN
Pin Map
40-QFN
Name
C2
23
28
P0.1
C1
24
29
VBUS_C_CTRL1
C4
24
30
VBUS_C_CTRL0
B1
25
31
VBUS
A1
26
32
12, 27
33
VSS
EPAD
EPAD
VSS
A2
28
34
P3.2
B2
N/A
35
P3.3
E3
Description
I2C_0_SCL / GPIO_OVT / UART_0_RTS / SPI_0_MISO/
TCPWM1
VBUS Gate Driver Control 1 for Consumer Switch
VBUS Gate Driver Control 0 for Consumer Switch
VBUS Input
VBUS_DISCHARGE VBUS Discharge Control output
Ground Supply (GND)
GPIO / TCPWM0
GPIO / TCPWM1
B3
29
36
P3.4
GPIO / UART_2_CTS / SPI_2_MOSI/ I2C_2_SDA /
TCPWM2
A3
30
37
P3.5
GPIO / UART_2_RTS / SPI_2_CLK/ I2C_2_SCL / TCPWM3
B4
N/A
38
P3.6
GPIO
A4
31
39
OC
Overcurrent sensor input
B5
32
40
VBUS_P
Document Number: 002-03288 Rev. *J
VBUS producer input
Page 10 of 45
EZ-PD™ CCG3
GPIO
GPIO
GPIO
GPIO
GND
VBUS_DISCHARGE
35
34
33
32
31
VBUS
GPIO
EPAD
14
15
16
17
18
19
20
AUX_N
GPIO
GPIO
VDDD
VDDIO
VCCD
30
VBUS_C_CTRL0
29
28
27
26
VBUS_C_CTRL1
GPIO_OVT
GPIO_OVT
XRES
25
24
23
22
21
GPIO
GPIO
GPIO
DMINUS
DPLUS
VSYS
12
13
SBU2
11
SBU1
8
9
10
AUX_P
GPIO
GPIO
GPIO
37
36
6
7
OC
VCONN
GPIO
38
2
3
4
5
VBUS_P
1
VBUS_P_CTRL0
CC2
V5V
CC1
39
VBUS_P_CTRL1
40
Figure 4. Pinout of 40-QFN Package (Top View)
Document Number: 002-03288 Rev. *J
VBUS_P
OC
GPIO
GPIO
GPIO
VSS
VBUS_DISCHARGE
VBUS
31
30
29
28
27
26
25
6
7
8
24
23
22
VBUS_C_CTRL
GPIO_OVT
GPIO_OVT
21
20
19
18
XRES
GPIO
12
13
14
15
16
VDDD
VDDIO
VCCD
VSYS
VSS
11
10
17
GPIO
GPIO
SBU1
EPAD
9
GPIO
GPIO
GPIO
1
2
3
4
5
SBU2
VBUS_P_CTRL
CC2
V5V
CC1
32
Figure 5. Pinout of 32-QFN Package (Top View)
GPIO
DMINUS
DPLUS
Page 11 of 45
EZ-PD™ CCG3
Figure 6. Pinout of 42-WLCSP Bottom (Balls Up) View
6
5
VBUS_P_CT VBUS_P_CT
RL0
RL1
4
3
2
1
OC
GPIO
P3.5
GPIO
P3.2
VBUS_DISC
HARGE
A
CC2
VBUS_P
GPIO
P3.6
GPIO
P3.4
GPIO
P3.3
VBUS
B
CC1
CC2
VBUS_C_CT
RL0
GPIO_OVT
P0.0
GPIO_OVT
P0.1
VBUS_C_CT
RL1
C
CC1
GPIO
P1.1
V5V
GPIO
P2.5
GPIO
P2.6
XRES
D
VCONN
GPIO
P1.2
AUX_P
VSS
GPIO
P2.4
DMINUS
E
GPIO
P1.0
SBU1
GPIO
P2.0
VDDIO
VCCD
DPLUS
F
GPIO
P1.3
SBU2
AUX_N
GPIO
P2.1
VDDD
VSYS
G
Document Number: 002-03288 Rev. *J
Page 12 of 45
EZ-PD™ CCG3
Available Firmware and Software Tools
EZ-PD Configuration Utility
The EZ-PD Configuration Utility is a GUI-based Microsoft Windows application developed by Cypress to guide a CCGx user through
the process of configuring and programming the chip. The utility allows users to:
1. Select and configure the parameters they want to modify
2. Program the resulting configuration onto the target CCGx device.
The utility works with the Cypress supplied CCG1, CCG2, CCG3, and CCG4 kits, which host the CCGx controllers along with a USB
interface. This version of the EZ-PD Configuration Utility supports configuration and firmware update operations on CCGx controllers
implementing EMCA and Display Dongle applications. Support for other applications, such as Power Adapters and Notebook port
controllers, will be provided in later versions of the utility.
You can download the EZ-PD Configuration Utility and its associated documentation at the following link:
http://www.cypress.com/documentation/software-and-drivers/ez-pd-configuration-utility
Document Number: 002-03288 Rev. *J
Page 13 of 45
EZ-PD™ CCG3
CCG3 Programming and Bootloading
There are two ways to program application firmware into a CCG3
device:
1. Programming the device flash over SWD Interface
2. Application firmware update over specific interfaces (CC,
USB, I2C)
Generally, the CCG3 devices are programmed over SWD
interface only during development or during the manufacturing
process of the end product. Once the end product is manufactured, the CCG3 device's application firmware can be updated
via the appropriate bootloader interface.
Programming the Device Flash over SWD Interface
The CCG3 family of devices can be programmed using the SWD
interface. Cypress provides a programming kit (CY8CKIT-002
MiniProg3 Kit) called MiniProg3 which can be used to program
the flash as well as debug firmware. The flash is programmed by
downloading the information from a hex file. This hex file is a
binary file generated as an output of building the firmware project
in PSoC Creator Software. Click here for more information on
how to use the MiniProg3 programmer. There are many
third-party programmers that support mass programming in a
manufacturing environment.
As shown in the block diagram in Figure 7, the SWD_0_DAT and
SWD_0_CLK pins are connected to the host programmer's
SWDIO (data) and SWDCLK (clock) pins respectively. During
SWD programming, the device can be powered by the host
programmer by connecting its VTARG (power supply to the
target device) to VSYS pin of CCG3 device. If the CCG3 device
is powered using an on-board power supply, it can be
programmed using the “Reset Programming” option. For more
details, refer to the CYPD3XXX Programming Specifications.
The CYPD3105 device for Thunderbolt cable applications is
pre-programmed with a micro-bootloader that allows users to
program the flash using the alternate SWD pins (SBU1 for
SWD_1_CLK and SBU2 for SWD_1_DAT) that can be
connected to the SBU interface of a Type-C connector. Note that
this interface can be used to program the flash only once. Subsequent re-programming of this device can be done through the
primary SWD interface (SWD_0_CLK and SWD_0_DAT pins).
Irrespective of which SWD interface is used for programming the
device, once the device is programmed with the hex file provided
by Cypress for thunderbolt cable application, subsequent
updates to the application firmware can be done over the CC
line. Refer to Application Firmware Update over Specific Interfaces (I2C, CC, USB) for more details.
Figure 7. Connecting the Programmer to CYPD3xxx Device
3.0 V
VDD
Host Programmer
CYPD3xxx
VCCD
VDD
VSYS
SWDCLK
SWD_0_CLK
SWDIO
SWD_0_DAT
XRES
1F
10V
X7R
VDDD
XRES
GND
VSS
VDDIO
1F
10V
X7R
GND
Application Firmware Update over Specific Interfaces
(I2C, CC, USB)
The application firmware can be updated over three different
interfaces depending on the default firmware programmed into
the CCG3 device. Refer to Table 38 for more details on default
firmware that various part numbers of the CCG3 family of
devices are pre-programmed with (note that some of the devices
have bootloader only and some have bootloader plus application
firmware). The application firmware provided by Cypress for all
CCG3 applications have dual images. This allows fail-safe
update of the alternate image while executing from the current
image. For more information, refer to the EZ-PD Configuration
Utility User Manual.
Document Number: 002-03288 Rev. *J
Application Firmware Update over I2C Interface
This method primarily applies to CYPD3122, CYPD3125, and
CYPD3126 devices of the CCG3 family. In these applications,
the CCG3 device interfaces to an on-board application
processor or an embedded controller over I2C interface. Refer to
Figure 8 for more details. Cypress provides pseudo-code for the
host processor for updating the CCG3 device firmware.
Page 14 of 45
EZ-PD™ CCG3
Figure 8. Application Firmware Update over I2C Interface
VDDD
2.2K
2.2K
2.2K
I2C_SDA
I2C_SCL
Embedded Controller/
Application Processor
I2C_INT
CYPD3xxx Device
To be Programmed
Application Firmware Update over CC Line
This method primarily applies to the CYPD3135 device of the
CCG3 family. In these applications, the CY4531 CCG3 EVK can
be used to send programming and configuration data as Cypress
specific Vendor Defined Messages (VDMs) over the CC line. The
CY4531 CCG3 EVK is connected to the system containing the
CCG3 device on one end and a Windows PC running the
EZ-PDTM Configuration Utility as shown in Figure 9 on the other
end to program the CCG3 device.
Figure 9. Application Firmware Update over CC Line
USB Serial Device of
CCG3 Daughter Card
PC
Running
EZ-PD Configuration
Utility
USB Mini-B
cable
I2C
CC Line
CCG3 Device on
CCG3 Daughter Card
Mini-B
Receptacle
CY4531 CCG3 EVK
Application Firmware Update over USB
This method primarily applies to the CYPD3120 and CYPD3121
devices of the CCG3 family. In these applications, the firmware
update can be performed over the D+/D- lines (USB2.0) using
various possible options as shown in Figure 10. Option 1 is to
have a Windows PC running EZ-PD Configuration Utility
connected to the device to be programmed via the CY4531
CCG3 EVK. This setup can be avoided using option 2, where the
Document Number: 002-03288 Rev. *J
CYPD3135 device
to be Programmed
Type-C
Receptacle
user has a Type-A to Type-C cable. This option requires that the
system contain the CCG3 device to be programmed to have a
Type-C receptacle. The other option (Option 3) is to have a
Windows PC with a native Type-C connector as shown in
Figure 10.
Page 15 of 45
EZ-PD™ CCG3
Figure 10. Application Firmware Update over USB
Option 1
PC
Running
EZ-PD Configuration
Utility
USB Type-A to
Type-B cable
Type-B
Receptacle
D+/D-
CY4531 CCG3 EVK
CYPD 312x device
to be Programmed
Type-C
Receptacle
OR
Option 2
USB Type-A to
Type-C cable
PC
Running
EZ-PD Configuration
Utility
CYPD 312x device
to be Programmed
OR
Option 3
Windows PC with
Native Type-C
Connector Running
EZ-PD Configuration
Utility
CYPD 312x device
to be Programmed
Type-C
Receptacle
Document Number: 002-03288 Rev. *J
Type-C plug
Page 16 of 45
EZ-PD™ CCG3
Applications
Figure 11 illustrates the application diagram of a power adapter
using a CCG3 device. In this application, CCG3 is used as DFP
(power provider) only. The maximum power profile that can be
supported by power adapters is up to 20 V, 100 W using 40-pin
QFN CCG3 devices. CCG3 has the ability to drive both types of
FETs and the state of GPIO P1.0 (floating or grounded) indicates
the type of FET (N-MOS or P-MOS FET) being used in the power
provider path.
The power provider FETs are controlled by high-voltage gate
driver outputs (VBUS_P_CTRL0 and VBUS_P_CTRL1 pins of
CCG3 device). The CCG3 device is also capable of supporting
proprietary charging protocols over the DP and DM lines of the
Type-C receptacle. By providing a 5-V source at the V5V pin of
the CCG3 device, the device becomes capable of delivering the
VCONN supply over either the CC1 or CC2 pins of the Type-C
connector.
CCG3 integrates all termination resistors and uses GPIOs
(VSEL0 and VSEL1) to indicate the negotiated power profile. If
required, the power profile can also be selected using CCG3
serial interfaces (I2C, SPI) or PWM. The VBUS voltage on the
Type-C port is monitored using internal circuits to detect undervoltage and overvoltage conditions. To ensure quick discharge
of VBUS when the power adapter cable is detached, a discharge
path is provided with a resistor connected to the VBUS_DISCHARGE pin of the CCG3 device.
The CCG3 family's power adapter parts are shipped with
bootloader and application firmware with limited functionality. Its
purpose is to facilitate application flashing over CC line using the
EZ-PD Configuration Utility. The power adapter requires an
explicit power contract to be negotiated prior to enabling the
EZ-PD Configuration utility to flash the application firmware. This
application firmware, based on the state of the GPIO (P1.0),
determines the type of provider load switch (NFET/PFET) and
supplies the 5-V VBUS over Type-C.
Overcurrent protection is enabled by sensing the current through
the 10-m sense resistor using the “OC” and “VBUS_P” pins of
the CCG3 device. The VBUS provider through the Type-C
connector can be turned on or off using the provider path FETs.
Figure 11. Power Adapter Application Diagram (40-QFN Device)
DC/DC
OR
AC-DC Secondary
(5-20V)
VBUS_OC
VBUS_IN
D
10 m 1%
VBUS_OUT
DMN3018SSD-13
DMN3018SSD-13
S
S
VBUS
D
G
G
10M
10F
50V
10M
VSEL1 VSEL2
100
2
39
28
27
40
31
1F
50V
X7R
33
X
20
17
18
1F
10V
X7R
X
X
X
11
14
6
OC
VSEL2/P0.0
VBUS_P_CTRL0
VBUS_P_CTRL1
VSEL1/P0.1
VBUS_DISCHARGE
CC1
VBUS
VBUS_C_CTRL1
GND
CYPD3135-40LQXIT
40QFN VBUS_C_CTRL0
VSYS
VDDD
V5V
VDDIO
P2.4
AUX_P
DPLUS
AUX_N
DMINUS
VCONN
GPIO
XRES
VCCD
26
19
1.3F
10V
X7R
Document Number: 002-03288 Rev. *J
32
CC2 3
VBUS_P
0.1F
1
SBU1 SBU2
P1.0
13
X
7
X
12
X
CC2
5
29
CC1
X
30 X
4
5V
VBUS_OUT
390pF
5%
X7R
390pF
5%
X7R
Type-C
Receptacle
100K
23
21
10K
22
8, 9, 10, 15, 16, 24, 25,
34, 35, 36, 37, 38
P1.0 indicates FET type in design.
Floating condition indicates NFETs
and connected to GND indicates
PFETs in provider path.
GND
Page 17 of 45
EZ-PD™ CCG3
The CCG3 device negotiates power contracts between the
power bank and the sink/source device connected to the Type-C
receptacle. The CCG3 device also controls and drives the
provider and consumer path FETs and can monitor overcurrent
and overvoltage conditions on the Type-C VBUS line.
Figure 12 illustrates a power bank application diagram using a
CCG3 device. In this application, the Type-C receptacle is used
for providing as well as consuming power. The consumer path
will be active when the battery is charged using a Type-C power
source that is connected to the Type-C receptacle in Figure 12.
The provider path will be active when the power bank is used for
providing power to a sink device connected to the Type-C receptacle. Additionally, a Type-A receptacle can also be provided for
providing power to the sinks that have a legacy USB interface.
Figure 12. Power Bank Application Diagram (40-QFN Device)
Consumer Path
D
10M
S
D
DMN3018SSD-13
D
1F
35V
X7R
7, 8, 15, 16, 23,
24, 25, 27, 28, 38
17
0.1F
10V
0.1F
10V
1F
10V
18
10F
50V
10M
1
2
VBUS_P_CTRL0 VBUS_P_CTRL1
4
V5V
X
31
VBUS
40
VBUS_P
20
1F
10V
D
G
10M
39
VBATT
10M
CCG3 gate driver control configuration
needs to be appropriately set, based
on the VBUS FET type (nFET/pFET).
DMN3018SSD-13
S
S
G
OC
VBUS
G
VBUS
Provider Path
10 m 1%
0.1F
10V
S
G
Power
Subsystem
+
Battery
0.1F
10V
DMN3018SSD-13
DMN3018SSD-13
VBUS_C_CTRL1
29
VBUS
VSYS
VBUS_C_CTRL0
GPIO
VBUS_DISCHARGE
VDDD
VDDIO
CYPD3121-40LQXIT
40QFN
CC1
DPLUS
13
GPIO/SBU2
X
37
I2C_SCL/GPIO
36
I2C_SDA/GPIO
34
GPIO
DMINUS
VCCD
35
19
32
CC2
5
6
CC1
AUX_N/GPIO
14
X
X
26
33
0.1F
10V
X7R
1uF
10V
X7R
Document Number: 002-03288 Rev. *J
Discrete Ckts to
support Legacy
Charge Source
SS
DP
DN
GND
From Power
Subsystem
CCG3
GPIO
Type-C
Receptacle
390pF
5%
X7R
22
11
X
GND
I2C_
I2C_
SCL/GPIO SDA/GPIO
9
10
390pF
5%
X7R
X
21
AUX_P/GPIO
XRES
GPIO
30
CC2 3
VCONN
12
GPIO/SBU1
X
100
VBUS
Type-A
Receptacle
DP
DN
GND
Page 18 of 45
EZ-PD™ CCG3
Figure 13 illustrates a USB Type-C to DisplayPort (4-lane) adapter application, which enables connectivity between a PC that supports
a Type-C port with DisplayPort Alternate Mode support and a legacy monitor that has a DisplayPort interface.
The application meets the requirements described in Section 4.2 of the VESA DisplayPort Alt Mode on USB Type-C Standard Version
1.0 (Scenarios 2a and 2b USB Type-C to DisplayPort Cables).
Figure 13. USB Type-C to DisplayPort Adapter Application Diagram
4
31
VCONN
0.1F
10V
1F
10V
1F
10V
40
20
7, 8, 15, 16, 24,
25, 27, 28, 38
0.1F
10V
1F
10V
mDP/
DP
V5V
VBUS_C_CTRL1
18
37
34
11
14
35
29
VBUS
VBUS_P
VCONN
VBUS_C_CTRL0
VDDD
VDDIO
CYPD3120-40LQXIT
40QFN
CC1
DPLUS
I2C_INT / P3.2
DMINUS
AUX_P
SBU1
AUX_N
SBU2
HOTPLUG_DET / P3.3
P2.4
VCCD
23
19
X
P2.4 indicates type of end application. Floating
condition indicates usage for Type-C to DP
application and connected to GND indicates
usage for Type-C to HDMI adapter application.
30
VCONN
0.1F
10V
32
CC2 3
I2C_SCL / P3.5
I2C_SDA / P3.4
VBUS
6
VSYS
VBUS_DISCHARGE
36
HotPlug Detect
VBUS_P_CTRL0 VBUS_P_CTRL1
GPIO
17
1F
10V
1
2
39
OC
XRES
MUX_I2C_ MUX_I2C_ GND
SCL/P1.2 SDA/P1.3
9
10
5
CC
390pF
5%
21 X7R
Type-C Plug
DP
22
DN
12
SBU1
13
SBU2
26
33
SS
0.1F
10V
X7R
GND
1F
10V
X7R
Display Port Data Lanes
Document Number: 002-03288 Rev. *J
Page 19 of 45
EZ-PD™ CCG3
Figure 14 illustrates a USB Type-C to HDMI adapter application, which enables connectivity between a PC that supports a Type-C
port with DisplayPort Alternate Mode support and a legacy monitor that has HDMI interface. It enables users of any Notebook that
implements USB-Type C to connect to other display types.
This application meets the requirements described in Section 4.3 of the VESA DisplayPort Alt Mode on USB Type-C Standard Version
1.0. This application supports display output at a resolution of up to 4K Ultra HD (3840x2160) at 60 Hz.
Figure 14. USB Type-C to HDMI Adapter Application
1.2V
VBUS
5V
3.3V
Regulator
VCONN
Power
OR
BuckBoost
5V BuckBoost not
needed for DVI/VGA
4
31
VCONN
0.1uF
10V
1uF
10V
40
1uF
10V
20
7, 8, 15, 16, 24,
25, 27, 28, 38
VBUS_P_CTRL0 VBUS_P_CTRL1
VBUS_C_CTRL1
V5V
P2.4
VBUS
VBUS_P
VCONN
VBUS_C_CTRL0
GPIO
VBUS_DISCHARGE
18
17
1uF
10V
0.1uF
10V
1uF
10V
37
36
34
11
14
VDDIO
VDDD
CYPD3120-40LQXIT
40QFN
3.3V
23
CC1
I2C_SCL / P3.5
I2C_SDA / P3.4
DPLUS
I2C_INT / P3.2
P2.4 indicates type of end application.
Floating condition indicates usage for
Type-C to DP application and connected
to GND indicates usage for Type-C to
HDMI adapter application.
6
30
VBUS
VCONN
0.1uF
10V
32
CC2 3
DMINUS
AUX_P
SBU1
AUX_N
SBU2
XRES
AUX_P/N
29
VSYS
3.3V
HDMI/
DVI/
VGA
1
2
39
OC
MUX_I2C_ MUX_I2C_ GND
35 HOTPLUG_
DET / P3.3 VCCD SCL/P1.2 SDA/P1.3
19
10
9
1uF
HotPlug
10V
Detect
X7R
5
CC
Type-C
Plug
390pF
5%
21 X7R
DP
22
DN
12
SBU1
13
SBU2
26
33
SS
0.1uF
10V
X7R
GND
1.2V
DP to HDMI/
DVI/VGA
Convertor
Document Number: 002-03288 Rev. *J
Display Port
Data Lanes
Page 20 of 45
EZ-PD™ CCG3
Figure 15 illustrates a Notebook DRP application diagram using a CCG3 device. The Type-C port can be used as a power provider
or a power consumer. The CCG3 device communicates with the embedded controller (EC) over I2C. It also controls the Data Mux to
route the HighSpeed signals either to the USB chipset (during normal mode) or the DisplayPort Chipset (during Alternate Mode). The
SBU, SuperSpeed, and HighSpeed lines are routed directly from the Display Mux of the notebook to the Type-C receptacle.
Figure 15. DRP Application Diagram
VINT20
DMN3018SSD-13
DMN3018SSD-13
Charger
D
S
S
D
G
10M
G
10M
VBUS
VBUS_SUPPLY
DMN3018SSD-13
DC/DC
1uF
35V
X7R
10 m 1%
V3P3 and V5P0 are 3.3V and 5V
supplies coming from the motherboard.
V5P0
VBUS
4
31
40
V3P3
20
0.1uF
10V
0.1uF
10V
1uF
10V
7, 8, 15, 16, 23,
24, 25, 27, 28, 38
VDDD
0.1uF
10V
0.1uF
10V
17
18
1uF
10V
X
2.2K
2.2K
X
12
13
37
36
Embedded
Controller
USB
Chipset
DisplayPort
Chipset
D
34
D+/HPD
SS
10uF
50V
G
10M
10M
1
OC
VBUS_P_CTRL0 VBUS_P_CTRL1
V5V
VBUS_C_CTRL1
29
VBUS
VBUS_P
VBUS
VSYS
VBUS_C_CTRL0
GPIO
VBUS_DISCHARGE
VDDD
VDDIO
CYPD3125-40LQXIT
40QFN
SBU1
CC1
DPLUS
SBU2
DMINUS
I2C_SCL / P3.5
AUX_P
I2C_SDA / P3.4
AUX_N
I2C_INT / P3.2
XRES
HOTPLUG_
MUX_I2C_ MUX_I2C_ GND
DET / P3.3 VCCD SCL/P1.2 SDA/P1.3
35
19
9
10
1uF
10V
X7R
HPD
SCL
SDA
100
30
32
CC2 3
VCONN
VDDD
2.2K
S
S
G
2
39
CCG3 gate driver control configuration
needs to be appropriately set, based
on the VBUS FET type (nFET/pFET).
D
DMN3018SSD-13
CC2
5
6
CC1
390pF
5%
X7R
X
21
390pF
5%
X7R
Type-C
Receptacle
22
11
14
X
X
26
33
0.1uF
10V
X7R
D+/-
SS
DP/DN
GND
HS/SS/
DP/SBU
Lines
SS
DP0/1/2/3
AUX+/-
Document Number: 002-03288 Rev. *J
Data Mux
Page 21 of 45
EZ-PD™ CCG3
Figure 16 illustrates a CCG3 device based Charge-through
Dongle application block diagram. This Charge-through dongle
application also implements Cypress’s USB SuperSpeed Hub
controller HX3 (CYUSB3304-68LTXI) available in 68-QFN
package, Low-power single chip USB 3.0 to Gigabit Ethernet
Bridge Controller GX3 (CYUSB3610-68LTXC) available in
68-QFN package and the CCG2 (CYPD2122-24LQXI) which
acts as an Upstream Facing Port (UFP) and sinks power when
connected to USB Type-C chargers.
This application enables connectivity between a USB Type-C
Notebook and HDMI Display, legacy USB device and Gigabit
Ethernet while also connecting a USB Type-C charging cable.
The Charge-Through Dongle solution allows simultaneous HDMI
display, Superspeed data transfers, Ethernet connection and
charging of a USB Type-C Notebook. Charge-Through Dongle is
also widely known as Multiport Adapter. More details including
the schematic of the CCG3 device based Charge-through
Dongle reference design can be found here.
Figure 16. Charge-through Dongle Application Block Diagram (40-QFN Device)
VBUS_C
VBUS_N
VCONN_N
Power
5.0V
3.3V
1.2V
3.3V
2x lane DP
4
1.2V
5V
DP to HDMI
Protocol Convertor
MegaChips
MCDP2900
HDMI
Receptacle
To Display
VBUS_A
SS/HS lines
DS1
Cypress
HX3
DS2
CYUSB304CYUSB3304
HS lines
68-QFN
4 SS lines
8
DS3
3.3V 1.2V
To Notebook
VBUS_N
VCONN_N
Legacy USB
devices
5V
Cypress GX3
CYUSB3610
68-QFN
Type-C plug
USB3.1
Type-A
Receptacle
Ethernet Port
HS lines
VBUS_C
CC
CCG3
DRP
CYPD3123
40-QFN
Document Number: 002-03288 Rev. *J
I2C
CCG2
UFP
CC
CYPD2122
24-QFN
Type-C receptacle
for Charging
From DFP
Charger
Page 22 of 45
EZ-PD™ CCG3
Electrical Specifications
Absolute Maximum Ratings
Table 3. Absolute Maximum Ratings
Parameter
Description
Min
Typ
Max
Units
VSYS_MAX
Digital supply relative to VSS
–0.5
–
6
V
V5V
Max supply voltage relative to VSS
–
–
6
V
VBUS_MAX_ON
Max supply voltage relative to VSS,
VBUS regulator enabled
–
–
26
V
Max supply voltage relative to VSS,
VBUS regulator enabled 100% of the
time
–
–
24.5
V
Max supply voltage relative to VSS,
VBUS regulator enabled 25% of the
time
–
–
26
V
VDDIO_MAX
Max supply voltage relative to VSS
–
–
6
V
VGPIO_ABS
GPIO voltage
VBUS_MAX_OFF
–0.5
–
VDDIO + 0.5
V
VGPIO_OVT_ABS OVT GPIO voltage
–0.5
–
6
V
IGPIO_ABS
Maximum current per GPIO
–25
–
25
mA
VCONN_MAX
Max voltage relative to VSS
–
–
6
V
VCC_ABS
Max voltage on CC1 and CC2 pins
–
–
6
V
–0.5
–
0.5
mA
GPIO injection current, Max for VIH >
IGPIO_INJECTION
VDDD, and Min for VIL < VSS
Details/Conditions
Absolute max
Absolute max, current injected per pin
ESD_HBM
Electrostatic discharge human body
model
2200
–
–
V
–
ESD_CDM
Electrostatic discharge charged
device model
500
–
–
V
–
LU
Pin current for latch-up
–100
–
100
mA
ESD_IEC_CON Electrostatic discharge IEC61000-4-2 8000
–
–
V
Contact discharge on CC1, CC2, VBUS,
DPLUS, DMINUS, SBU1 and SBU2 pins
ESD_IEC_AIR
–
–
V
Air discharge for CC1, CC2, VBUS,
DPLUS, DMINUS, SBU1 and SBU2 pins
Electrostatic discharge IEC61000-4-2 15000
Document Number: 002-03288 Rev. *J
Tested at 125 °C
Page 23 of 45
EZ-PD™ CCG3
Device-Level Specifications
All specifications are valid for –40 °C  TA  105 °C and TJ  120 °C, except where noted.
Table 4. DC Specifications
Spec ID
Parameter
SID.PWR#1
VSYS
SID.PWR#1_A
VSYS
Description
Min
Typ
Max
Units
–
2.7
–
5.5
V
UFP Mode.
–
DFP/DRP or Gate Driver Modes
SID.PWR#23
VCONN
Power Supply Input
Voltage
SID.PWR#13
VDDIO
IO Supply Voltage
SID.PWR24
VCCD
Output Voltage for core
Logic
SID.PWR#4
IDD
Supply current
SID.PWR#1_B
VSYS
SID.PWR#1_C
Details/Conditions
3
–
5.5
V
2.7
–
5.5
V
1.71
–
5.5[2]
V
–
1.8
–
V
–
From VSYS or VBUS
VBUS = 5V,
TA = 25 °C / VSYS = 5 V, TA = 25 °C
FS USB, CC IO in Tx or Rx, no I/O sourcing
current, 2 SCBs at 1 Mbps, CPU at 24 MHz.
–
2.7V < VDDD < 5.5 V
–
25
–
mA
Power supply for USB
operation
4.5
–
5.5
V
USB configured, USB Regulator enabled
VSYS
Power supply for USB
operation
3.15
–
3.45
V
USB configured, USB Regulator disabled
SID.PWR#1_D
VSYS
Power supply for charger
detect/emulation
operation
3.15
–
5.5
V
–40 °C to +85 °C TA
SID.PWR#27
VBUS
Power supply input
voltage
3.5
–
21.5
V
FS USB disabled. Total current consumption
from VBUS <15 mA.
SID.PwR#28
VBUS
Power supply input
voltage for USB operation
4.5
–
21.5
V
FS USB configured, USB Regulator disabled
SID.PWR#30
VBUS_P
Power supply input
voltage
4.00
–
21.5
V
SID.PWR#15
Cefc
External regulator voltage
bypass for VCCD
1
1.3
1.6
µF
X5R ceramic or better
SID.PWR#16
Cexc
Power supply decoupling
capacitor for VSYS
0.8
1
–
µF
X5R ceramic or better
Sleep Mode. VSYS = 2.7 V to 5.5 V. Typical values measured at VDD = 3.3 V and TA = 25 °C.
SID25A
CC, I2C, WDT wakeup
on.
IMO at 48 MHz.
–
3.5
–
mA
VSYS = 3.3 V, TA = 25 °C, All blocks except
CPU are on, CC IO on, USB in Suspend
Mode, no I/O sourcing current
IDD_DS
VSYS = 3.0 to 3.6 V. CC
Attach, I2C, WDT
Wakeup on.
–
30
–
µA
Power Source = VSYS, DFP Mode, Type-C
Not Attached. CC Attach, I2C and WDT
enabled for Wakeup.
IDD_XR
Supply current while
XRES asserted.
This does not include
current drawn due to the
XRES internal pull-up
resistor.
–
30
–
µA
Power Source = VSYS = 3.3 V, Type-C
device not attached,
TA = 25 °C
IDD20A
Deep Sleep Mode
SID_DS
XRES Current
SID307
Note
2. If VDDIO > VDDD, GPIO P2.4 cannot be used. It must be left unconnected. See Table 2 for pin numbers.
Document Number: 002-03288 Rev. *J
Page 24 of 45
EZ-PD™ CCG3
Table 5. AC Specifications (Guaranteed by Characterization)
Spec ID
SID.CLK#4
Parameter
FCPU
Description
Min
CPU input frequency
Typ Max Units
DC
–
48
Details/Conditions
MHz All VDDD
SID.PWR#20 TSLEEP
Wakeup from sleep mode
–
0
–
µs
–
SID.PWR#21 TDEEPSLEEP
Wakeup from Deep Sleep mode
–
–
35
µs
–
SID.XRES#5 TXRES
External reset pulse width
5
–
–
µs
SYS.FES#1
Power-up to “Ready to accept I2C/CC
command”
–
5
25
ms
T_PWR_RDY
All VDDIO
–
I/O
Table 6. I/O DC Specifications
Spec ID
Parameter
Description
Min
Typ
Max
Units
Details/Conditions
SID.GIO#37
VIH_CMOS
Input voltage HIGH threshold 0.7 × VDDIO
–
–
V
CMOS input
SID.GIO#38
VIL_CMOS
Input voltage LOW threshold
–
–
0.3 × VDDIO
V
CMOS input
SID.GIO#39
VIH_VDDIO2.7-
LVTTL input, VDDIO < 2.7 V
0.7× VDDIO
–
–
V
–
SID.GIO#40
VIL_VDDIO2.7-
LVTTL input, VDDIO < 2.7 V
–
–
0.3 × VDDIO
V
–
SID.GIO#41
VIH_VDDIO2.7+ LVTTL input, VDDIO  2.7 V
2.0
–
–
V
–
SID.GIO#42
VIL_VDDIO2.7+
LVTTL input, VDDIO  2.7 V
–
–
0.8
V
–
SID.GIO#33
VOH_3V
Output voltage HIGH level
VDDIO –0.6
–
–
V
IOH = 4 mA at 3V VDDIO
SID.GIO#34
VOH_1.8V
Output voltage HIGH level
VDDIO –0.5
–
–
V
IOH = 1 mA at 1.8V VDDIO
SID.GIO#35
VOL_1.8V
Output voltage LOW level
–
–
0.6
V
IOL = 4 mA at 1.8V VDDIO
SID.GIO#36
VOL_3V
Output voltage LOW level
–
–
0.6
V
IOL = 4 mA at 3V VDDIO
for SBU and AUX pins
SID.GIO#5
RPU
Pull-up resistor value
3.5
5.6
8.5
k
+25 °C TA, all VDDIO
SID.GIO#6
RPD
Pull-down resistor value
3.5
5.6
8.5
k
+25 °C TA, all VDDIO
SID.GIO#16
IIL
Input leakage current
(absolute value)
–
–
2
nA
+25 °C TA, all VDDIO.
Guaranteed by
characterization.
Max pin capacitance
–
3.0
7
pF
All VDDIO, all packages,
all I/Os except SBU and
AUX. Guaranteed by
characterization.
SID.GIO#17A CPIN_SBU
Max pin capacitance
–
16
18
pF
All VDDIO, all packages,
SBU pins only. Guaranteed
by characterization.
SID.GIO#17B CPIN_AUX
Max pin capacitance
–
12
14
pF
All VDDIO, all packages,
AUX pins only. Guaranteed
by characterization.
SID.GIO#43
VHYSTTL
Input hysteresis, LVTTL
VDDIO  2.7 V
15
40
–
mV
Guaranteed by
characterization
SID.GIO#44
VHYSCMOS
Input hysteresis CMOS
0.05 × VDDIO
–
–
mV
VDDIO < 4.5 V.
Guaranteed by characterization.
SID69
IDIODE
Current through protection
diode to VDDIO/Vss
–
–
100
µA
Guaranteed by characterization
SID.GIO#45
ITOT_GPIO
Maximum total sink chip
current
–
–
85
mA
Guaranteed by characterization
SID.GIO#17
CPIN
Document Number: 002-03288 Rev. *J
Page 25 of 45
EZ-PD™ CCG3
Table 6. I/O DC Specifications (continued)
Spec ID
Parameter
Description
Min
Typ
Max
Units
–
–
10.00
µA
Details/Conditions
OVT
SID.GIO#46
Input current when Pad >
VDDIO for OVT inputs
IIHS
Per I2C specification
Table 7. I/O AC Specifications
(Guaranteed by Characterization)
Spec ID
Parameter
Description
Min
Typ Max Units
Details/Conditions
SID70
TRISEF
Rise time in Fast Strong mode
2
–
12
ns
3.3 V VDDIO, Cload = 25 pF
SID71
TFALLF
Fall time in Fast Strong mode
2
–
12
ns
3.3 V VDDIO, Cload = 25 pF
XRES
Table 8. XRES DC Specifications
Spec ID
Parameter
SID.XRES#1 VIH_XRES
SID.XRES#2 VIL_XRES
SID.XRES#3 CIN_XRES
SID.XRES#4 VHYSXRES
Description
Input voltage HIGH
threshold on XRES pin
Input voltage LOW
threshold on XRES pin
Input capacitance on
XRES pin
Input voltage hysteresis
on XRES pin
Min
Typ
Max
Units
Details/Conditions
0.7 × VDDIO
–
–
V
CMOS input
–
–
0.3 × VDDIO
V
CMOS input
–
–
7
pF
–
0.05 × VDDIO
–
mV
Guaranteed by characterization
Guaranteed by characterization
Digital Peripherals
The following specifications apply to the Timer/Counter/PWM peripherals in the Timer mode.
Pulse Width Modulation (PWM) for GPIO Pins
Table 9. PWM AC Specifications
(Guaranteed by Characterization)
Spec ID
Parameter
Description
SID.TCPWM.3
TCPWMFREQ Operating frequency
SID.TCPWM.4
TPWMENEXT Input trigger pulse width
SID.TCPWM.5
TPWMEXT
Min
Typ
Max
Units
–
–
Fc
MHz
2/Fc
–
–
ns
Output trigger pulse width
2/Fc
–
–
ns
SID.TCPWM.5A TCRES
Resolution of counter
1/Fc
–
–
ns
SID.TCPWM.5B PWMRES
PWM resolution
1/Fc
–
–
ns
SID.TCPWM.5C QRES
Quadrature inputs resolution
1/Fc
–
–
ns
Document Number: 002-03288 Rev. *J
Details/Conditions
Fc max = CLK_SYS.
Maximum = 48 MHz.
For all trigger events
Minimum possible width of
Overflow, Underflow, and CC
(Counter equals Compare
value) outputs
Minimum time between
successive counts
Minimum pulse width of PWM
output
Minimum pulse width between
quadrature-phase inputs
Page 26 of 45
EZ-PD™ CCG3
I2C
Table 10. Fixed I2C DC Specifications
(Guaranteed by Characterization)
Description
Min
Typ
Max
Units
Details/Conditions
SID149
Spec ID
II2C1
Parameter
Block current consumption at 100 kHz
–
–
60
µA
–
SID150
II2C2
Block current consumption at 400 kHz
–
–
185
µA
–
SID151
II2C3
Block current consumption at 1 Mbps
–
–
390
µA
–
SID152
II2C4
I2C enabled in Deep Sleep mode
–
–
1.4
µA
–
Min
Typ
Max
Units
Details/Conditions
–
–
1
Mbps
–
Min
Typ
Max
Units
Details/Conditions
Table 11. Fixed I2C AC Specifications
(Guaranteed by Characterization)
Spec ID
SID153
Parameter
FI2C1
Description
Bit rate
Table 12. Fixed UART DC Specifications
(Guaranteed by Characterization)
Spec ID
Parameter
Description
SID160
IUART1
Block current consumption at
100 Kb/s
–
–
125
µA
–
SID161
IUART2
Block current consumption at
1000 Kb/s
–
–
312
µA
–
Description
Min
Typ
Max
Units
Details/Conditions
Bit rate
–
–
1
Mbps
–
Table 13. Fixed UART AC Specifications
(Guaranteed by Characterization)
Spec ID
SID162
Parameter
FUART
Table 14. Fixed SPI DC Specifications
(Guaranteed by Characterization)
Min
Typ
Max
Units
Details/Conditions
SID163
Spec ID
ISPI1
Parameter
Block current consumption at 1 Mb/s
Description
–
–
360
µA
–
SID164
ISPI2
Block current consumption at 4 Mb/s
–
–
560
µA
–
SID165
ISPI3
Block current consumption at 8 Mb/s
–
–
600
µA
–
Table 15. Fixed SPI AC Specifications
(Guaranteed by Characterization)
Spec ID
Description
Min
Typ
Max
Units
Details/Conditions
SPI Operating frequency (Master; 6X
oversampling)
–
–
8
MHz
–
Description
Min
Typ
Max
Units
Details/Conditions
TDMO
MOSI Valid after SClock driving edge
–
–
15
ns
SID168
TDSI
MISO Valid before SClock capturing
edge
20
–
–
ns
Full clock, late MISO
sampling
SID169
THMO
Previous MOSI data hold time
0
–
–
ns
Referred to slave capturing
edge
SID166
Parameter
FSPI
Table 16. Fixed SPI Master Mode AC Specifications
(Guaranteed by Characterization)
Spec ID
SID167
Parameter
Document Number: 002-03288 Rev. *J
–
Page 27 of 45
EZ-PD™ CCG3
Table 17. Fixed SPI Slave Mode AC Specifications
(Guaranteed by Characterization)
Spec ID
Parameter
Description
Min
Typ
Max
Units
Details/Conditions
40
–
–
ns
–
SID170
TDMI
MOSI Valid before Sclock capturing
edge
SID171
TDSO
MISO Valid after Sclock driving edge
–
–
42 + 3 × TCPU
ns
SID171A
TDSO_EXT
MISO Valid after Sclock driving edge
in Ext Clk mode
–
–
48
ns
–
SID172
THSO
Previous MISO data hold time
0
–
–
ns
–
SID172A
TSSELSCK
SSEL Valid to first SCK Valid edge
100
–
–
ns
–
TCPU = 1/FCPU
System Resources
Power-on-Reset (POR) with Brown Out SWD Interface
Table 18. Imprecise Power On Reset (PRES) (Guaranteed by Characterization)
Spec ID
Parameter
Description
Min
Typ
Max
Units
Details/Conditions
SID185
VRISEIPOR
Power-on Reset (POR) rising trip
voltage
0.80
–
1.50
V
–
SID186
VFALLIPOR
POR falling trip voltage
0.70
–
1.4
V
–
Table 19. Precise Power On Reset (POR) (Guaranteed by Characterization)
Spec ID
Parameter
Description
Min
Typ
Max
Units
Details/Conditions
1.48
–
1.62
V
–
1.1
–
1.5
V
–
Min
Typ
SID190
VFALLPPOR
Brown-out Detect (BOD) trip voltage
in active/sleep modes
SID192
VFALLDPSLP
BOD trip voltage in Deep Sleep mode
Table 20. SWD Interface Specifications
Spec ID
Parameter
Description
Max
Units
Details/Conditions
SID.SWD#1
F_SWDCLK1
3.3 V  VDDIO  5.5 V
–
–
14
SWDCLK 1/3 CPU clock
MHz
frequency
SID.SWD#2
F_SWDCLK2
1.8 V  VDDIO  3.3 V
–
–
7
MHz
SID.SWD#3
T_SWDI_SETUP T = 1/f SWDCLK
0.25 × T
–
–
ns
Guaranteed by
characterization
SID.SWD#4
T_SWDI_HOLD
0.25 × T
–
–
ns
Guaranteed by
characterization
SID.SWD#5
T_SWDO_VALID T = 1/f SWDCLK
–
–
0.50 × T
ns
Guaranteed by
characterization
SID.SWD#6
T_SWDO_HOLD T = 1/f SWDCLK
1
–
–
ns
Guaranteed by
characterization
T = 1/f SWDCLK
Document Number: 002-03288 Rev. *J
SWDCLK 1/3 CPU clock
frequency
Page 28 of 45
EZ-PD™ CCG3
Internal Main Oscillator
Table 21. IMO DC Specifications
(Guaranteed by Design)
Spec ID
SID218
Parameter
IIMO1
Description
IMO operating current at 48 MHz
Min
Typ
Max
Units
Details/Conditions
–
–
1000
µA
–
Min
Typ
Max
Units
Details/Conditions
Table 22. IMO AC Specifications
Spec ID
Parameter
Description
SID.CLK#13
FIMOTOL
Frequency variation at 24, 36, and
48 MHz (trimmed)
–
–
±2
%
–25 °C TA 85 °C, all VDDD
SID226
TSTARTIMO
IMO start-up time
–
–
7
µs
Guaranteed by
characterization
SID229
TJITRMSIMO2
RMS jitter at 24 MHz
–
145
–
ps
Guaranteed by
characterization
SID.CLK#1
FIMO
IMO frequency
24
–
48
MHz All VDDD
Internal Low-Speed OscillatorPower Down
Table 23. ILO DC Specifications
(Guaranteed by Design)
Min
Typ
Max
Units
Details/Conditions
SID231
Spec ID
IILO1
Parameter
ILO operating current
Description
–
0.3
1.05
µA
–
SID233
IILOLEAK
ILO leakage current
–
2
15
nA
–
Min
Typ
Max
Units
Details/Conditions
Table 24. ILO AC Specifications
Spec ID
Parameter
Description
SID234
TSTARTILO1
ILO start-up time
–
–
2
ms
Guaranteed by
characterization
SID238
TILODUTY
ILO duty cycle
40
50
60
%
Guaranteed by
characterization
SID.CLK#5
FILO
ILO frequency
20
40
80
kHz
–
Description
Min
Typ
Max
Units
Details/Conditions
RP_std
DFP CC termination for default USB
Power
64
80
96
µA
–
Table 25. PD DC Specifications
Spec ID
SID.PD.1
Parameter
SID.PD.2
RP_1.5A
DFP CC termination for 1.5A power
166
180
194.4
µA
–
SID.PD.3
RP_3.0A
DFP CC termination for 3.0A power
304
330
356.4
µA
–
SID.PD.4
RD
UFP CC termination
4.59
5.1
5.61
kΩ
–
SID.PD.5
RD_DB
UFP Dead Battery CC termination on
CC1 and CC2, valid for 1.5A and 3.0A
RP termination values
4.08
5.1
6.12
kΩ
UFP Dead Battery CC
termination on CC1 and CC2.
For Default RP termination,
the voltage on CC1 and CC2
is guaranteed to be <1.32 V.
SID.PD.6
RA
EMCA cable termination
0.8
1.0
1.2
kΩ
All supplies forced to 0 V and
0.2 V applied at VCONN.
SID.PD.7
RA_OFF
EMCA cable termination - Disabled
0.4
0.75
–
MΩ
2.7 V applied at VCONN with
RA disabled.
Document Number: 002-03288 Rev. *J
Page 29 of 45
EZ-PD™ CCG3
Table 25. PD DC Specifications (continued)
Spec ID
Parameter
Description
Min
Typ
Max
Units
SID.PD.8
Rleak_1
VCONN leaker for 0.1-µF load
–
–
216
kΩ
SID.PD.9
Rleak_2
VCONN leaker for 0.5-µF load
–
–
43.2
kΩ
SID.PD.10
Rleak_3
VCONN leaker for 1.0-µF load
–
–
21.6
kΩ
SID.PD.11
Rleak_4
VCONN leaker for 2.0-µF load
–
–
10.8
kΩ
SID.PD.12
Rleak_5
VCONN leaker for 5.0-µF load
–
–
4.32
kΩ
SID.PD.13
Rleak_6
VCONN leaker for 10-µF load
–
–
2.16
kΩ
SID.PD.14
Ileak
Leaker on VCONN for discharge
upon cable detach
150
–
550
µA
SID.PD.15
Vgndoffset
Ground offset tolerated by BMC
receiver
–400
–
400
mV
Details/Conditions
Managed Active Cable (MAC)
discharge.
–
Relative to the remote BMC
transmitter. Guaranteed by
characterization.
Table 26. CSA Specifications
Spec ID
Parameter
Description
Min
Typ
Max
Units Details/Conditions
–
7.00
%
Guaranteed by
characterization.
Guaranteed by
characterization.
SID.CSA.1
Overall Error at Av = 15 using deep sleep
Out_E_Trim_15_DS
–7.00
reference
SID.CSA.2
Out_E_Trim_15_BG
Overall Error at Av = 15 using bandgap
reference
–4.50
–
4.50
%
SID.CSA.3
Out_E_Trim_100
Overall Error at Av = 100 using either
bandgap or deep sleep reference
–24.50
–
24.50
%
–
Table 27. UV/OV Specifications
Spec ID
Parameter
Description
Min
SID.UVOV.1
VTHUVOV1
Voltage threshold Accuracy,
VBUS  16 V
SID.UVOV.2
VTHUVOV2
Voltage threshold Accuracy,
VBUS  16 V
Typ
Max
Units
Details/Conditions
–6
6
%
Tested at VBUS = 3.75 V,
4.5 V, 5.25 V, 12 V, 16 V
–10
10
%
Tested at VBUS = 20 V
Gate Driver Specifications
Table 28. Gate Driver DC Specifications
Spec ID
DC.NGDO.1
Parameter
VGS1
Description
Gate to Source
Overdrive
DC.NGDO.2
VGS2
Gate to Source
Overdrive
DC.NGDO.6
RPD
Resistance when “pull
down” enabled
Document Number: 002-03288 Rev. *J
Min
5
Typ
–
Max Units
16.5
Details/Conditions
V
1. Gate driver Supply Voltage  5V, where
Gate driver supply voltage = VBUS _P for
VBUS_P_CTRL_ outputs, and VBUS_C
for VBUS_C_CTRL_ outputs.
2. Gate driver current = 0
3. Gate driver configuration = NFET
4. Gate driver pump clock divider = 1
3.75
–
16.5
V
1. Gate driver Supply Voltage  3.75V, where
Gate driver supply voltage = VBUS _P for
VBUS_P_CTRL_ outputs, and VBUS_C
for VBUS_C_CTRL_ outputs.
2. Gate driver current = 0
3. Gate driver configuration = NFET
4. Gate driver pump clock divider = 1
–
–
5
kΩ
–
Page 30 of 45
EZ-PD™ CCG3
Table 29. Gate Driver AC Specifications
Spec ID
Parameter
AC.NGDO.1 TON
Description
Min
Gate turn-on time to gate_driver_supply_voltage + 5V for supply voltage 
5V and VBUS * 2 for supply voltage <
5V
Typ
–
Max
–
1
Units
ms
Details/Conditions
1. Gate driver configuration =
NFET
2. Load = The gate of a SI9936
MOSFET
SBU
Table 30. Analog Crossbar Switch Specifications
Spec ID
Parameter
Description
Min
Typ
Max
Units
Details/Conditions
SID.SBU.1
Ron_sw
Switch ON Resistance
–
–
10
Ω
Voltage input from 0 V
to 3.6 V
SID.SBU.2
Rpu_aux_1
AUX_P/N Pull-up Resistance – 100k
80
–
120
kΩ
–
SID.SBU.3
Rpu_aux_2
AUX_P/N Pull-up Resistance – 1M
0.8
–
1.2
MΩ
–
SID.SBU.4
Rpd_aux_1
AUX_P/N Pull-down Resistance – 100k
80
–
120
kΩ
–
SID.SBU.5
Rpd_aux_2
AUX_P/N Pull-down Resistance – 1M
0.8
–
1.2
MΩ
–
SID.SBU.6
Rpd_aux_3
AUX_P/N Pull-down Resistance – 470k
329
–
611
kΩ
–
SID.SBU.7
Rpd_aux_4
AUX_P/N Pull-down Resistance – 4.7M
3.29
–
6.11
MΩ
–
Charger Detect
Table 31. Charger Detect Specifications
Spec ID
SID.CD.1
Parameter
VDAT_REF
Description
Min
Typ
Max
Units
BC1.2 Data Detect Voltage Threshold
250
–
400
mV
Details/Conditions
–
SID.CD.2
VDM_SRC
BC1.2 DM Voltage Source
500
–
700
mV
With current sink of
25 µA–175 µA
SID.CD.3
VDP_SRC
BC1.2 DP Voltage Source
500
–
700
mV
With current sink of
25 µA–175 µA
SID.CD.4
IDM_SINK
BC1.2 DM Current Sink
25
–
175
µA
–
SID.CD.5
IDP_SINK
BC1.2 DP Current Sink
25
–
175
µA
–
SID.CD.6
IDP_SRC
BC1.2 DP DCD Current Source
7
–
13
µA
–
SID.CD.7
RDP_UP
USB FS DP Pull-up Termination
0.9
–
1.575
kΩ
–
SID.CD.8
RDM_UP
USB FS DM Pull-up Termination
0.9
–
1.575
kΩ
–
SID.CD.9
RDP_DWN
USB FS DP Pull-down Termination
14.25
–
24.8
kΩ
–
SID.CD.10
RDM_DWN
USB FS DM Pull-down Termination
14.25
–
24.8
kΩ
–
SID.CD.11
RDAT_LKG
DP/DM Data Line Leakage Termination
300
–
500
kΩ
The charger detect function
and data line leakage is
enabled.
SID.CD.12
RDCP_DAT
BC1.2 DCP Port Resistance between
DP and DM
–
–
40
Ω
–
SID.CD.13
VSETH
USB FS Logic Threshold
1.26
–
1.54
V
–
Document Number: 002-03288 Rev. *J
Page 31 of 45
EZ-PD™ CCG3
Analog to Digital Converter
Table 32. ADC DC Specifications (Guaranteed by Characterization)
Spec ID
Parameter
Description
Min
Typ
Max
Units
Details/Conditions
SID.ADC.1
Resolution
ADC resolution
–
8
–
Bits
–
SID.ADC.2
INL
Integral non-linearity
–1.5
–
1.5
LSB
–
SID.ADC.3
DNL
Differential non-linearity
–2.5
–
2.5
LSB
–
SID.ADC.4
Gain Error
Gain error
–1
–
1
LSB
–
Table 33. ADC AC Specifications (Guaranteed by Design)
Spec ID
SID.ADC.5
Parameter
Description
Min
Typ
Max
Units
Details/Conditions
–
–
3
V/ms
–
Rate of change of sampled voltage
signal
SLEW_Max
Table 34. VBUS_C Regulator DC Specifications
Spec ID
Parameter
Description
Min
Typ
Max
Units
SID.20vreg.1 VBUSREG
VBUS regulator output voltage
measured at VDDD for
VBUS = 4.5 V to 21.5 V
3
–
3.6
V
VBUS = 4.5 V - 21.5 V range.
VDDD voltage measured with no
load and a load of 30 mA.
SID.20vreg.2 VBUSREG2
VBUS regulator output voltage
measured at VDDD for
VBUS = 3.5 V to 21.5 V
3
–
3.6
V
VBUS = 4.5 V - 21.5 V range.
VDDD voltage measured with no
load and a load of 15 mA.
SID.20vreg.6 VBUSLINREG
VBUS regulator line regulation
for VBUS from 4.5 V to 21.5 V
–
–
0.5
%/V
VBUS supply varied from 4.5 V to
21.5 V and the change in the VDDD
measured.
Guaranteed by Characterization.
SID.20vreg.8 VBUSLOADREG
VBUS regulator load regulation
for VBUS from 4.5 V to 21.5 V
–
–
Details/Conditions
Supply of 4.5 V - 21.5 V applied on
VBUS and the load current swept
%/mA from 0 to 30 mA. The change in
VDDD is measured.
Guaranteed by Characterization.
0.2
Table 35. VBUS_C Regulator AC Specifications (Guaranteed by Characterization)
Spec ID
Parameter
Description
Min Typ Max Units
Details/Conditions
AC.20vreg.1 TSTART
Regulator Start-up time
–
–
120
µs
Apply VBUS and measure start time on
VDDD pin.
AC.20vreg.2 TSTOP
Regulator power down time
–
–
1
µs
Time from assertion of an internal disable
signal to for load current on VDDD to
decrease from 30 mA to 10 µA.
Table 36. VSYS Switch Specification
Spec ID
Parameter
SID.vddsw.1 Res_sw
Description
Resistance from VSYS supply
input to the output supply
VDDD
Document Number: 002-03288 Rev. *J
Min Typ Max Units
–
–
1.5
Ω
Details/Conditions
Measured with a load current of 5 mA - 10 mA
on VDDD.
Page 32 of 45
EZ-PD™ CCG3
Memory
Table 37. Flash AC Specifications
Spec ID
Parameter
Description
Min Typ Max
Units
Details/Conditions
SID.MEM#3 FLASH_ERASE
Row erase time
–
–
15.5
ms
–
SID.MEM#4 FLASH_WRITE
Row (Block) write time (erase
and program)
–
–
20
ms
–
SID.MEM#8 FLASH_ROW_PGM Row program time after erase
–
–
7
ms
–
SID178
TBULKERASE
Bulk erase time (64k Bytes)
–
–
35
ms
–
SID180
TDEVPROG
Total device program time
–
–
7.5
s
Guaranteed by characterization
SID182
FRET1
Flash retention, TA ≤ 55 °C,
100 K P/E cycles
20
–
–
years
Guaranteed by characterization
SID182A
FRET2
Flash retention, TA ≤ 85 °C,
10 K P/E cycles
10
–
–
years
Guaranteed by characterization
SID182B
FRET3
Flash retention, TA ≤ 105 °C,
10 K P/E cycles
3
–
–
years
Guaranteed by characterization
Document Number: 002-03288 Rev. *J
Page 33 of 45
EZ-PD™ CCG3
Ordering Information
Table 38 lists the EZ-PD CCG3 part numbers and features.
Table 38. EZ-PD CCG3 Ordering Information
Part Number
CYPD3120-40LQXIT
CYPD3120-40LQXI
CYPD3121-40LQXIT
CYPD3121-40LQXI
CYPD3122-40LQXIT
CYPD3122-40LQXI
CYPD3123-40LQXIT
CYPD3123-40LQXI
CYPD3125-40LQXIT
CYPD3125-40LQXI
CYPD3126-42FNXIT
CYPD3135-32LQXQT
CYPD3135-32LQXQ
CYPD3135-40LQXIT
CYPD3135-40LQXI
CYPD3135-40LQXQT
CYPD3135-40LQXQ
Application
Termination Resistor
Role
Default FW
Package
Si ID
Dongle
RP, RD[4], RD_DB
UFP
USB Bootloader
and Application FW
40-QFN
1D00
Power Banks
RP[5], RD, RD_DB[6]
DRP
USB Bootloader
40-QFN
1D02
Monitor (DFP)
RP, RD, RD_DB
DFP
I2C Bootloader
40-QFN
1D03
Charge-through Dongle
RP, RD, RD_DB
DRP
USB Bootloader
and Application FW
40-QFN
1D09
Notebooks, Smartphones RP, RD, RD_DB
DRP
I2C Bootloader
40-QFN
1D04
DRP
RP, RD[4], RD_DB
DRP
I2C Bootloader
42-CSP
1D07
Power Adapter
RP
DFP
CC Bootloader and
Application FW[7]
32-QFN
1D08
Power Adapter
RP
DFP
CC Bootloader and
Application FW[7]
40-QFN
1D05
Power Adapter
RP
DFP
CC Bootloader and
Application FW[7]
40-QFN
1D05
Ordering Code Definitions
CY PD
X
X XX -
XX XX
X X X
T = Tape and Reel
Temperature Grade:
I = Industrial (–40 °C - 85 °C), Q = Extended industrial (–40 °C - 105 °C)
Lead: X = Pb-free
Package Type: FN = CSP; LQ = QFN
Number of pins in the package
Application and Feature Combination Designation
Number of Type-C Ports: 1 = 1 Port, 2 = 2 Port
Product Type: 3 = Third-generation product family, CCG3
Marketing Code: PD = Power Delivery product family
Company ID: CY = Cypress
Notes
3. Termination resistor denoting an EMCA.
4. Termination resistor denoting an upstream facing port.
5. Termination resistor denoting a downstream facing port.
6. Termination resistor denoting dead battery termination.
7. The CYPD3135 parts are shipped with bootloader and application firmware with limited functionality. Its purpose is to facilitate application flashing over CC line using
the EZ-PD Configuration Utility. The power adapter requires an explicit power contract to be negotiated prior to enabling the EZ-PD Configuration utility to flash the
application firmware. This application firmware, based on the state of the GPIO (P1.0), determines the type of provider load switch (NFET/PFET) and supplies the
5V VBUS over Type-C.
Document Number: 002-03288 Rev. *J
Page 34 of 45
EZ-PD™ CCG3
Packaging
Table 39. Package Characteristics
Parameter
Description
Conditions
Industrial
Min
Typ
–40
25
–40
25
TA
Operating ambient temperature
TJ
Operating junction temperature
TJA
Package JA (40-pin QFN)
–
–
TJC
Package JC (40-pin QFN)
–
–
TJA
Package JA (42-ball WLCSP)
–
–
TJC
Package JC (42-ball WLCSP)
–
–
TJA
Package JA (32-pin QFN)
–
TJC
Package JC (32-pin QFN)
–
Extended Industrial
Industrial
Extended Industrial
Max
Units
85
°C
105
°C
100
°C
125
°C
–
17
°C/W
–
2
°C/W
–
34
°C/W
–
0.3
°C/W
–
–
18
°C/W
–
–
4
°C/W
Table 40. Solder Reflow Peak Temperature
Maximum Peak Temperature
Maximum Time within 5 °C of Peak
Temperature
40-pin QFN
260 °C
30 seconds
42-ball WLCSP
260 °C
30 seconds
32-pin QFN
260 °C
30 seconds
Package
Table 41. Package Moisture Sensitivity Level (MSL), IPC/JEDEC J-STD-2
Package
MSL
42-ball WLCSP
MSL 1
40-pin QFN
MSL 3
32-pin QFN
MSL 3
Document Number: 002-03288 Rev. *J
Page 35 of 45
EZ-PD™ CCG3
Figure 17. 40-pin QFN Package Outline, 001-80659
001-80659 *A
Figure 18. 42-ball CSP Package Outline, 002-04062
002-04062 *A
Document Number: 002-03288 Rev. *J
Page 36 of 45
EZ-PD™ CCG3
Figure 19. 32-pin QFN Package Outline, 001-42168
SEE NOTE 1
TOP VIEW
BOTTOM VIEW
SIDE VIEW
DIMENSIONS
MIN.
NOM.
MAX.
HATCH AREA IS SOLDERABLE EXPOSED PAD
2. BASED ON REF JEDEC # MO-248
A
0.50
0.55
0.60
3. PACKAGE WEIGHT: 0.0388g
A1
-
0.020
0.045
4. DIMENSIONS ARE IN MILLIMETERS
A2
0.15 BSC
D
4.90
5.00
5.10
D2
3.40
3.50
3.60
E
4.90
5.00
5.10
E2
3.40
3.50
3.60
L
0.30
0.40
0.50
b
0.18
0.25
0.30
e
Document Number: 002-03288 Rev. *J
NOTES:
1.
SYMBOL
001-42168 *F
0.50 TYP
Page 37 of 45
EZ-PD™ CCG3
Acronyms
Table 42. Acronyms Used in this Document (continued)
Table 42. Acronyms Used in this Document
Acronym
Description
ADC
analog-to-digital converter
AES
advanced encryption standard
AHB
AMBA (advanced microcontroller bus architecture)
high-performance bus
Acronym
Description
opamp
operational amplifier
OCP
overcurrent protection
OVP
overvoltage protection
PCB
printed circuit board
PD
power delivery
programmable gain amplifier
API
application programming interface
PGA
ARM®
advanced RISC machine, a CPU architecture
PHY
physical layer
BMC
Biphase Mark Code
POR
power-on reset
CC
configuration channel
PRES
precise power-on reset
CCG3
Cable Controller Generation 3
PSoC®
Programmable System-on-Chip™
CPU
central processing unit
PWM
pulse-width modulator
CRC
cyclic redundancy check, an error-checking
protocol
RAM
random-access memory
RISC
reduced-instruction-set computing
CS
current sense
RMS
root-mean-square
DFP
downstream facing port
RTC
real-time clock
DIO
digital input/output, GPIO with only digital capabilities, no analog. See GPIO.
RX
receive
DRP
dual role port
EEPROM
electrically erasable programmable read-only
memory
SAR
successive approximation register
SCB
serial communication block
SCL
I2C serial clock
SDA
I2C serial data
EMCA
electronically marked cable assembly, a USB cable
that includes an IC that reports cable
characteristics (e.g., current rating) to the Type-C
ports
S/H
sample and hold
SHA
secure hash algorithm
EMI
electromagnetic interference
SPI
ESD
electrostatic discharge
Serial Peripheral Interface, a communications
protocol
FS
full-speed
SRAM
static random access memory
GPIO
general-purpose input/output
SWD
serial wire debug, a test protocol
HPD
hot plug detect
TCPWM
timer/counter pulse-width modulator
IC
integrated circuit
Thunderbolt
Trademark of Intel
IDE
integrated development environment
TX
transmit
Type-C
a new standard with a slimmer USB connector and
a reversible cable, capable of sourcing up to 100 W
of power
I2C,
or IIC
Inter-Integrated Circuit, a communications protocol
ILO
internal low-speed oscillator, see also IMO
IMO
internal main oscillator, see also ILO
IOSS
input/output subsystem
UART
Universal Asynchronous Transmitter Receiver, a
communications protocol
I/O
input/output, see also GPIO
USB
Universal Serial Bus
LDO
low-dropout regulator
USB PD
USB Power Delivery
LVD
low-voltage detect
USB-FS
USB Full-Speed
LVTTL
low-voltage transistor-transistor logic
MCU
microcontroller unit
USBIO
USB input/output, CCG2 pins used to connect to a
USB port
MMIO
memory mapped input/output
USBPD SS USB PD subsystem
NC
no connect
VDM
vendor defined messages
NMI
nonmaskable interrupt
XRES
external reset I/O pin
NVIC
nested vectored interrupt controller
Document Number: 002-03288 Rev. *J
Page 38 of 45
EZ-PD™ CCG3
Document Conventions
Units of Measure
Table 43. Units of Measure
Symbol
Unit of Measure
°C
degrees Celsius
Hz
hertz
KB
1024 bytes
kHz
kilohertz
k
kilo ohm
Mbps
megabits per second
MHz
megahertz
M
mega-ohm
Msps
megasamples per second
µA
microampere
µF
microfarad
µs
microsecond
µV
microvolt
µW
microwatt
mA
milliampere
ms
millisecond
mV
millivolt
nA
nanoampere
ns
nanosecond

ohm
pF
picofarad
ppm
parts per million
ps
picosecond
s
second
sps
samples per second
V
volt
Document Number: 002-03288 Rev. *J
Page 39 of 45
EZ-PD™ CCG3
References and Links to Applications Collaterals
Knowledge Base Articles
■
Key Differences Among EZ-PD™ CCG1, CCG2, CCG3 and
CCG4 - KBA210740
■
AN95615 - Designing USB 3.1 Type-C Cables Using EZ-PD™
CCG2
■
Programming EZ-PD™ CCG2, EZ-PD™ CCG3 and EZ-PD™
CCG4 Using PSoC® Programmer and MiniProg3 - KBA96477
■
AN95599 - Hardware Design Guidelines for EZ-PD™ CCG2
CCGX Frequently Asked Questions (FAQs) - KBA97244
■
■
AN210403 - Hardware Design Guidelines for Dual Role Port
Applications Using EZ-PD™ USB Type-C Controllers
■
Handling Precautions for CY4501 CCG1 DVK - KBA210560
■
AN210771 - Getting Started with EZ-PD™ CCG4
■
Cypress EZ-PD™ CCGx Hardware - KBA204102
Reference Designs
■
Difference between USB Type-C and USB-PD - KBA204033
■
CCGx Programming Methods - KBA97271
■
Getting started with Cypress USB Type-C Products KBA04071
■
Type-C to DisplayPort Cable Electrical Requirements
■
Dead Battery Charging Implementation in USB Type-C
Solutions - KBA97273
■
■
EZ-PD™ CCG2 Electronically Marked Cable Assembly
(EMCA) Paddle Card Reference Design
■
EZ-PD™ CCG2 USB Type-C to DisplayPort Cable Solution
■
CCG1 USB Type-C to DisplayPort Cable Solution
■
CCG1 USB Type-C to HDMI/DVI/VGA Adapter Solution
■
EZ-PD™ CCG2 USB Type-C to HDMI Adapter Solution
Termination Resistors Required for the USB Type-C Connector
– KBA97180
■
CCG1 Electronically Marked Cable Assembly (EMCA) Paddle
Card Reference Design
■
VBUS Bypass Capacitor Recommendation for Type-C Cable
and Type-C to Legacy Cable/Adapter Assemblies – KBA97270
■
CCG1 USB Type-C to Legacy USB Device Cable Paddle Card
Reference Schematics
■
Need for Regulator and Auxiliary Switch in Type-C to
DisplayPort (DP) Cable Solution - KBA97274
■
EZ-USB GX3 USB Type-C to Gigabit Ethernet Dongle
■
Need for a USB Billboard Device in Type-C Solutions –
KBA97146
■
EZ-PD™ CCG2 USB Type-C Monitor/Dock Solution
■
CCG2 20W Power Adapter Reference Design
■
CCG1 Devices in Type-C to Legacy Cable/Adapter Assemblies
– KBA97145
■
CCG2 18W Power Adapter Reference Design
Cypress USB Type-C Controller Supported Solutions –
KBA97179
■
■
EZ-USB GX3 USB Type-A to Gigabit Ethernet Reference
Design Kit
■
Termination Resistors for Type-C to Legacy Ports – KBA97272
■
Handling Instructions for CY4502 CCG2 Development Kit –
KBA97916
■
Thunderbolt™ Cable Application Using CCG3 Devices KBA210976
■
Power Adapter Application Using CCG3 Devices - KBA210975
■
Methods to Upgrade Firmware on CCG3 Devices - KBA210974
■
Device Flash Memory Size and Advantages - KBA210973
■
Applications of EZ-PD™ CCG4 - KBA210739
Application Notes
■
AN96527 - Designing USB Type-C Products Using Cypress’s
CCG1 Controllers
Document Number: 002-03288 Rev. *J
Kits
■
CY4501 CCG1 Development Kit
■
CY4502 EZ-PD™ CCG2 Development Kit
■
CY4531 EZ-PD CCG3 Evaluation Kit
■
CY4541 EZ-PD™ CCG4 Evaluation Kit
Datasheets
■
CCG1 Datasheet: USB Type-C Port Controller with Power
Delivery
■
CYPD1120 Datasheet: USB Power Delivery Alternate Mode
Controller on Type-C
■
CCG2: USB Type-C Port Controller Datasheet
■
CCG4: Two-Port USB Type-C Controller Datasheet
Page 40 of 45
EZ-PD™ CCG3
Document History Page
Document Title: EZ-PD™ CCG3 USB Type-C Port Controller
Document Number: 002-03288
Revision
ECN
Orig. of
Change
Submission
Date
**
4905678
VGT
09/11/2015
New data sheet.
10/08/2015
Updated General Description:
Updated the number of GPIOs to 20.
Updated Functional Overview:
Updated GPIO:
Updated the number of GPIOs to 20.
Updated Pinouts:
Updated Table 2.
Updated Figure 4.
Added Figure 6.
11/25/2015
Changed status from Advance to Preliminary.
Updated Features.
Added EZ-PD CCG3 Block Diagram.
Updated Functional Overview:
Updated USB-PD Subsystem (USBPD SS) (Updated description).
Added Full-Speed USB Subsystem.
Updated Pinouts:
Updated Table 2.
Updated Figure 4.
Updated Figure 6.
Added Applications.
Updated Electrical Specifications:
Updated Absolute Maximum Ratings:
Updated Table 3.
Updated Device-Level Specifications:
Updated Table 4.
Updated Table 5.
Updated I/O:
Updated Table 6.
Updated XRES:
Updated Table 8.
Updated System Resources:
Updated Power-on-Reset (POR) with Brown Out SWD Interface:
Updated Table 18.
Updated Table 19.
Updated Table 20.
Updated Internal Main Oscillator:
Updated Table 22.
Updated Internal Low-Speed OscillatorPower Down:
Updated Table 23.
Updated Table 24.
Updated Internal Low-Speed OscillatorPower Down:
Updated Table 25.
*A
*B
4953333
5007726
VGT
VGT
Document Number: 002-03288 Rev. *J
Description of Change
Page 41 of 45
EZ-PD™ CCG3
Document History Page (continued)
Document Title: EZ-PD™ CCG3 USB Type-C Port Controller
Document Number: 002-03288
Revision
*B (cont.)
*C
*D
*E
ECN
5007726
5080470
5137796
5240836
Orig. of
Change
VGT
VGT
VGT
VGT
Document Number: 002-03288 Rev. *J
Submission
Date
Description of Change
11/25/2015
Updated Analog to Digital Converter:
Updated Table 32.
Updated Table 33.
Updated Packaging:
Added Figure 18 (spec 002-04062 *A).
01/11/2016
Updated General Description.
Updated Features.
Updated Logic Block Diagram.
Updated Power Systems Overview.
Updated Pinouts:
Updated Table 2.
Added table “CCG3 Pin Description for 16-SOIC Device”.
Added figure “Pinout of 16-SOIC Package (Top View)”.
Updated Applications:
Updated Figure .
Updated Figure 11.
Updated figure “Power Adapter Application Diagram (16-SOIC Device)”.
Updated Figure 15.
Updated Ordering Information.
Updated Packaging:
Added spec 51-85022 *E.
Added Errata.
03/09/2016
Updated Pinouts:
Updated table “CCG3 Pin Description for 16-SOIC Device”.
Updated figure “Pinout of 16-SOIC Package (Top View)”.
Updated Applications:
Updated Figure 11.
Updated Figure 12.
Updated Ordering Information
Updated Errata.
Updated to new template.
04/28/2016
Updated General Description:
Updated description.
Updated Features:
Updated Type-C and USB-PD Support:
Updated description.
Updated Packages:
Updated description.
Updated Logic Block Diagram.
Updated Functional Overview:
Updated Integrated Billboard Device:
Updated description.
Updated USB-PD Subsystem (USBPD SS):
Updated description.
Added Figure 2 and Figure 5.
Page 42 of 45
EZ-PD™ CCG3
Document History Page (continued)
Document Title: EZ-PD™ CCG3 USB Type-C Port Controller
Document Number: 002-03288
Revision
*E (cont.)
*F
*G
ECN
5240836
5342389
5449433
Orig. of
Change
VGT
VGT
VGT
Document Number: 002-03288 Rev. *J
Submission
Date
Description of Change
04/28/2016
Updated Power Systems Overview: Updated description.
Updated Figure 3.
Updated Pinouts:
Updated Table 2:
Updated details in “Description” column corresponding to VDDIO pin.
Removed table “CCG3 Pin Description for 16-SOIC Device”.
Removed figure “Pinout of 16-SOIC Package (Top View)”.
Updated Applications: Removed figure “Power Adapter Application Diagram
(16-SOIC Device)”.
Added Figure 12.
Updated Electrical Specifications:
Updated Device-Level Specifications:
Updated Table 4.
Updated details in “Details/Conditions” column corresponding to
“SID.PWR#1_A” Spec ID and “VSYS” parameter.
Replaced “VDDD” with “5.5” in “Max” column corresponding to “SID.PWR#13”
Spec ID and “VDDIO” parameter.
Added “SID.PWR#13_A” Spec ID corresponding to “VDDIO” parameter and its
details.
Added “SID.PWR#1_C” and “SID.PWR#1_D” Spec IDs corresponding to
“VSYS” parameter and its details.
Replaced “enabled” with “disabled” in “Details/Conditions” column
corresponding to “SID.PwR#28” Spec ID and “VBUS” parameter.
Updated details in “Description” and “Details/Conditions” columns
corresponding to “SID307” Spec ID and “IDD_XR” parameter.
Updated System Resources:
Added Gate Driver Specifications, Charger Detect.
Updated Ordering Information: Updated part numbers.
Updated details in “Application” column corresponding to part number
“CYPD3121-40LQXIT”.
Updated Ordering Code Definitions
Updated Packaging: Removed spec 51-85022 *E.
Removed Errata.
07/28/2016
Added Available Firmware and Software Tools, CCG3 Programming and
Bootloading, and References and Links to Applications Collaterals.
Added descriptive notes for the application diagrams.
Updated Features, Applications and Timer/Counter/PWM Block (TCPWM).
Updated Table 2 through Table 6, Table 18, Table 19, Table 22, Table 23,
Table 25, and Table 31 through Table 38.
Updated Figure 7, Figure 8, Figure , Figure 11, and Figure 19 (package
diagram spec 001-42168 *E).
Added Figure 5, Figure 13, and Figure 14.
Added Table 26, Table 27, Table 37, and Table 39 through Table 41.
Added VDM in Acronyms.
Updated Cypress logo and copyright information.
09/26/2016
Added Table 34 through Table 36.
Updated Table 3, Table 4, Table 6, and Table 37.
Updated Copyright and Disclaimer.
Added Compliance information in Sales, Solutions, and Legal Information.
Page 43 of 45
EZ-PD™ CCG3
Document History Page (continued)
Document Title: EZ-PD™ CCG3 USB Type-C Port Controller
Document Number: 002-03288
Revision
ECN
Orig. of
Change
Submission
Date
Description of Change
*H
5514508
VGT
01/13/2017
Removed Preliminary document status.
Updated Sales information and Copyright details.
Added Gate Driver Specifications in Table 28 and Table 29.
Updated Applications.
Added Figure 16.
Updated Ordering Information:
Added “CYPD3123-40LQXIT” part number.
Removed “CYPD3105-42FNXIT” part number.
*I
5662219
VGT
03/29/2017
Updated Table 2, added non Tape and Reel part numbers and Note 7 in
Table 38, Updated description prior to Figure 11.
2/21/2018
Updated description of V5V pin in Table 2.
Removed parameter SID.PWR#13_A from Table 4.
Updated description in USB-PD Subsystem (USBPD SS).
Updated Packaging: 32-pin QFN Package Outline, 001-42168 (*E to *F).
*J
6032274
VGT
Document Number: 002-03288 Rev. *J
Page 44 of 45
EZ-PD™ CCG3
Sales, Solutions, and Legal Information
Worldwide Sales and Design Support
Cypress maintains a worldwide network of offices, solution centers, manufacturer’s representatives, and distributors. To find the office
closest to you, visit us at Cypress Locations.
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Products
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cypress.com/clocks
cypress.com/interface
Internet of Things
Memory
cypress.com/iot
cypress.com/memory
Microcontrollers
cypress.com/mcu
PSoC
cypress.com/psoc
Power Management ICs
Touch Sensing
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Wireless Connectivity
PSoC 1 | PSoC 3 | PSoC 4 | PSoC 5LP | PSoC 6
Cypress Developer Community
Forums | WICED IOT Forums | Projects | Video | Blogs |
Training | Components
Technical Support
cypress.com/support
cypress.com/pmic
cypress.com/touch
cypress.com/usb
cypress.com/wireless
Notice regarding compliance with Universal Serial Bus specification. Cypress offers firmware and hardware solutions that are certified to comply with the Universal Serial Bus specification, USB
Type-C™ Cable and Connector Specification, and other specifications of USB Implementers Forum, Inc (USB-IF). You may use Cypress or third party software tools, including sample code, to modify
the firmware for Cypress USB products. Modification of such firmware could cause the firmware/hardware combination to no longer comply with the relevant USB-IF specification. You are solely
responsible ensuring the compliance of any modifications you make, and you must follow the compliance requirements of USB-IF before using any USB-IF trademarks or logos in connection with any
modifications you make. In addition, if Cypress modifies firmware based on your specifications, then you are responsible for ensuring compliance with any desired standard or specifications as if you
had made the modification. CYPRESS IS NOT RESPONSIBLE IN THE EVENT THAT YOU MODIFY OR HAVE MODIFIED A CERTIFIED CYPRESS PRODUCT AND SUCH MODIFIED PRODUCT
NO LONGER COMPLIES WITH THE RELEVANT USB-IF SPECIFICATIONS.
© Cypress Semiconductor Corporation, 2015-2018. This document is the property of Cypress Semiconductor Corporation and its subsidiaries, including Spansion LLC ("Cypress"). This document,
including any software or firmware included or referenced in this document ("Software"), is owned by Cypress under the intellectual property laws and treaties of the United States and other countries
worldwide. Cypress reserves all rights under such laws and treaties and does not, except as specifically stated in this paragraph, grant any license under its patents, copyrights, trademarks, or other
intellectual property rights. If the Software is not accompanied by a license agreement and you do not otherwise have a written agreement with Cypress governing the use of the Software, then Cypress
hereby grants you a personal, non-exclusive, nontransferable license (without the right to sublicense) (1) under its copyright rights in the Software (a) for Software provided in source code form, to
modify and reproduce the Software solely for use with Cypress hardware products, only internally within your organization, and (b) to distribute the Software in binary code form externally to end users
(either directly or indirectly through resellers and distributors), solely for use on Cypress hardware product units, and (2) under those claims of Cypress's patents that are infringed by the Software (as
provided by Cypress, unmodified) to make, use, distribute, and import the Software solely for use with Cypress hardware products. Any other use, reproduction, modification, translation, or compilation
of the Software is prohibited.
TO THE EXTENT PERMITTED BY APPLICABLE LAW, CYPRESS MAKES NO WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, WITH REGARD TO THIS DOCUMENT OR ANY SOFTWARE
OR ACCOMPANYING HARDWARE, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. No computing
device can be absolutely secure. Therefore, despite security measures implemented in Cypress hardware or software products, Cypress does not assume any liability arising out of any security breach,
such as unauthorized access to or use of a Cypress product. In addition, the products described in these materials may contain design defects or errors known as errata which may cause the product
to deviate from published specifications. To the extent permitted by applicable law, Cypress reserves the right to make changes to this document without further notice. Cypress does not assume any
liability arising out of the application or use of any product or circuit described in this document. Any information provided in this document, including any sample design information or programming
code, is provided only for reference purposes. It is the responsibility of the user of this document to properly design, program, and test the functionality and safety of any application made of this
information and any resulting product. Cypress products are not designed, intended, or authorized for use as critical components in systems designed or intended for the operation of weapons, weapons
systems, nuclear installations, life-support devices or systems, other medical devices or systems (including resuscitation equipment and surgical implants), pollution control or hazardous substances
management, or other uses where the failure of the device or system could cause personal injury, death, or property damage ("Unintended Uses"). A critical component is any component of a device
or system whose failure to perform can be reasonably expected to cause the failure of the device or system, or to affect its safety or effectiveness. Cypress is not liable, in whole or in part, and you
shall and hereby do release Cypress from any claim, damage, or other liability arising from or related to all Unintended Uses of Cypress products. You shall indemnify and hold Cypress harmless from
and against all claims, costs, damages, and other liabilities, including claims for personal injury or death, arising from or related to any Unintended Uses of Cypress products.
Cypress, the Cypress logo, Spansion, the Spansion logo, and combinations thereof, WICED, PSoC, CapSense, EZ-USB, F-RAM, and Traveo are trademarks or registered trademarks of Cypress in
the United States and other countries. For a more complete list of Cypress trademarks, visit cypress.com. Other names and brands may be claimed as property of their respective owners.
Document Number: 002-03288 Rev. *J
Revised February 23, 2018
Page 45 of 45
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