CYUSB301X/CYUSB201X EZ-USB® FX3: SuperSpeed USB Controller Features Applications ■ ■ Digital video camcorders ■ Digital still cameras ■ Printers ■ Scanners ■ Video capture cards ■ Test and measurement equipment ■ Surveillance cameras ■ Personal navigation devices ■ Medical imsaging devices ■ Video IP phones ■ Portable media players ■ Industrial cameras ■ Data loggers ■ Data acquisition ■ High-performance Human Interface Devices (gesture recognition) ■ ■ ■ Universal serial bus (USB) integration ❐ USB 3.1, Gen 1 and USB 2.0 peripherals compliant with USB 3.1 Specification Revision 1.0 (TID # 340800007) ❐ 5-Gbps SuperSpeed PHY compliant with USB 3.1 Gen 1 ❐ High-speed On-The-Go (HS-OTG) host and peripheral compliant with OTG Supplement Version 2.0 ❐ Thirty-two physical endpoints ❐ Support for battery charging Specification 1.1 and accessory charger adaptor (ACA) detection General Programmable Interface (GPIF™ II) ❐ Programmable 100-MHz GPIF II enables connectivity to a wide range of external devices ❐ 8-, 16-, 24-, and 32-bit data bus ❐ Up to16 configurable control signals Fully accessible 32-bit CPU ❐ ARM926EJ core with 200-MHz operation ❐ 512-KB or 256-KB embedded SRAM Additional connectivity to the following peripherals ❐ SPI master at up to 33 MHz ❐ UART support of up to 4 Mbps 2 ❐ I C master controller at 1 MHz 2 ❐ I S master (transmitter only) at sampling frequencies of 32 kHz, 44.1 kHz, and 48 kHz ■ Selectable clock input frequencies ❐ 19.2, 26, 38.4, and 52 MHz ❐ 19.2-MHz crystal input support ■ Ultra low-power in core power-down mode ❐ Less than 60 µA with VBATT on and 20 µA with VBATT off ■ Independent power domains for core and I/O ❐ Core operation at 1.2 V ❐ I2S, UART, and SPI operation at 1.8 to 3.3 V 2 ❐ I C operation at 1.2 V to 3.3 V ■ Package options ❐ 121-ball, 10- × 10-mm, 0.8-mm pitch Pb-free ball grid array (BGA) ❐ 131-ball, 4.7- × 5.1-mm, 0.4-mm pitch wafer-level chip scale package (WLCSP) ❐ See Table 20 for details on the eight FX3 variants ■ EZ-USB® Software Development Kit (SDK) for code development of firmware and PC Applications ❐ Includes RTOS Framework (using ThreadX Version 5) ❐ Firmware examples covering all I/O modules ❐ Visual Studio host examples using C++ and C# ■ SuperSpeed Explorer Board available for rapid prototyping ❐ Several accessory boards also available: • Adapter boards for Xilinx/Altera FPGA development • Adapter board for Video development • CPLD board for concept testing and initial development Cypress Semiconductor Corporation Document Number: 001-52136 Rev. *S • For a complete list of related documentation, click here. 198 Champion Court • San Jose, CA 95134-1709 • 408-943-2600 Revised April 7, 2016 CYUSB301X/CYUSB201X Logic Block Diagram Document Number: 001-52136 Rev. *S Page 2 of 53 CYUSB301X/CYUSB201X More Information Cypress provides a wealth of data at www.cypress.com to help you to select the right <product> device for your design, and to help you to quickly and effectively integrate the device into your design. For a comprehensive list of resources, see the knowledge base article KBA87889, How to design with FX3/FX3S. ■ ■ ■ Overview: USB Portfolio, USB Roadmap USB 3.0 Product Selectors: FX3, FX3S, CX3, HX3, West Bridge Benicia Application notes: Cypress offers a large number of USB application notes covering a broad range of topics, from basic to advanced level. Recommended application notes for getting started with FX3 are: ❐ AN75705 - Getting Started with EZ-USB FX3 ❐ AN76405 - EZ-USB FX3 Boot Options ❐ AN70707 - EZ-USB FX3/FX3S Hardware Design Guidelines and Schematic Checklist ❐ AN65974 - Designing with the EZ-USB FX3 Slave FIFO Interface ❐ AN75779 - How to Implement an Image Sensor Interface with EZ-USB FX3 in a USB Video Class (UVC) Framework ❐ AN86947 - Optimizing USB 3.0 Throughput with EZ-USB FX3 ❐ AN84868 - Configuring an FPGA over USB Using Cypress EZ-USB FX3 ❐ AN68829 - Slave FIFO Interface for EZ-USB FX3: 5-Bit Address Mode ❐ AN73609 - EZ-USB FX2LP/ FX3 Developing Bulk-Loop Example on Linux ❐ AN77960 - Introduction to EZ-USB FX3 High-Speed USB Host Controller ❐ AN76348 - Differences in Implementation of EZ-USB FX2LP and EZ-USB FX3 Applications ❐ AN89661 - USB RAID 1 Disk Design Using EZ-USB FX3S ■ Code Examples: < Modify as required > ❐ USB Hi-Speed ❐ USB Full-Speed ❐ USB SuperSpeed ■ Technical Reference Manual (TRM): ❐ EZ-USB FX3 Technical Reference Manual ■ Development Kits: ❐ CYUSB3KIT-003, EZ-USB FX3 SuperSpeed Explorer Kit ❐ CYUSB3KIT-001, EZ-USB FX3 Development Kit ■ Models: IBIS EZ-USB FX3 Software Development Kit Cypress delivers the complete software and firmware stack for FX3, in order to easily integrate SuperSpeed USB into any embedded application. The Software Development Kit (SDK) comes with tools, drivers and application examples, which help accelerate application development. GPIF™ II Designer The GPIF II Designer is a graphical software that allows designers to configure the GPIF II interface of the EZ-USB FX3 USB 3.0 Device Controller. The tool allows users the ability to select from one of five Cypress supplied interfaces, or choose to create their own GPIF II interface from scratch. Cypress has supplied industry standard interfaces such as Asynchronous and Synchronous Slave FIFO, Asynchronous and Synchronous SRAM, and Asynchronous SRAM. Designers who already have one of these pre-defined interfaces in their system can simply select the interface of choice, choose from a set of standard parameters such as bus width (x8, 16, x32) endianess, clock settings, and compile the interface. The tool has a streamlined three step GPIF interface development process for users who need a customized interface. Users are able to first select their pin configuration and standard parameters. Secondly, they can design a virtual state machine using configurable actions. Finally, users can view output timing to verify that it matches the expected timing. Once the three step process is complete, the interface can be compiled and integrated with FX3. Document Number: 001-52136 Rev. *S Page 3 of 53 CYUSB301X/CYUSB201X Contents Functional Overview .......................................................... 5 Application Examples .................................................... 5 USB Interface ...................................................................... 6 OTG............................................................................... 6 ReNumeration ............................................................... 7 EZ-Dtect ........................................................................ 7 VBUS Overvoltage Protection ....................................... 7 Carkit UART Mode ........................................................ 7 GPIF II .................................................................................. 8 CPU ...................................................................................... 8 JTAG Interface .................................................................... 8 Other Interfaces .................................................................. 8 SPI Interface.................................................................. 8 UART Interface.............................................................. 9 I2C Interface.................................................................. 9 I2S Interface .................................................................. 9 Boot Options....................................................................... 9 Reset.................................................................................... 9 Hard Reset .................................................................... 9 Soft Reset...................................................................... 9 Clocking ............................................................................ 10 32-kHz Watchdog Timer Clock Input........................... 10 Power................................................................................. 11 Power Modes .............................................................. 11 Digital I/Os......................................................................... 13 GPIOs................................................................................. 13 System-level ESD ............................................................. 13 Pin Configurations ........................................................... 14 Document Number: 001-52136 Rev. *S Pin Description ................................................................. 15 Electrical Specifications .................................................. 19 Absolute Maximum Ratings......................................... 19 Operating Conditions................................................... 19 DC Specifications ........................................................ 19 AC Timing Parameters .....................................................21 GPIF II Timing ............................................................. 21 Slave FIFO Interface ................................................... 24 Host Processor Interface (P-Port) Timing ................... 30 Serial Peripherals Timing ............................................ 37 Reset Sequence.......................................................... 42 Package Diagram.............................................................. 43 Ordering Information........................................................ 45 Ordering Code Definitions ........................................... 45 Acronyms .......................................................................... 46 Document Conventions ................................................... 46 Units of Measure ......................................................... 46 Errata ................................................................................. 47 Qualification Status ..................................................... 47 Errata Summary .......................................................... 47 Document History Page ................................................... 50 Sales, Solutions, and Legal Information ........................ 53 Worldwide Sales and Design Support......................... 53 Products ...................................................................... 53 PSoC®Solutions ......................................................... 53 Cypress Developer Community................................... 53 Technical Support ....................................................... 53 Page 4 of 53 CYUSB301X/CYUSB201X Functional Overview Cypress’s EZ-USB FX3 is a SuperSpeed peripheral controller, providing integrated and flexible features. FX3 has a fully configurable, parallel, general programmable interface called GPIF II, which can connect to any processor, ASIC, or FPGA. GPIF II is an enhanced version of the GPIF in FX2LP, Cypress’s flagship USB 2.0 product. It provides easy and glueless connectivity to popular interfaces, such as asynchronous SRAM, asynchronous and synchronous address data multiplexed interfaces, and parallel ATA. FX3 has integrated the USB 3.1 Gen 1 and USB 2.0 physical layers (PHYs) along with a 32-bit ARM926EJ-S microprocessor for powerful data processing and for building custom applications. It implements an architecture that enables 375-MBps data transfer from GPIF II to the USB interface. An integrated USB 2.0 OTG controller enables applications in which FX3 may serve dual roles; for example, EZ-USB FX3 may function as an OTG Host to MSC as well as HID-class devices. FX3 contains 512 KB or 256 KB of on-chip SRAM (see Ordering Information on page 45) for code and data. EZ-USB FX3 also provides interfaces to connect to serial peripherals such as UART, SPI, I2C, and I2S. FX3 comes with application development tools. The software development kit comes with firmware and host application examples for accelerating time to market. FX3 complies with the USB 3.1, Gen 1.0 specification and is also backward compatible with USB 2.0. It also complies with the Battery Charging Specification v1.1 and USB 2.0 OTG Specification v2.0. Application Examples In a typical application (see Figure 1), the FX3 functions as the main processor running the application software that connects external hardware to the SuperSpeed USB connection. Additionally, FX3 can function as a coprocessor connecting via the GPIF II interface to an application processor (see Figure 2) and operates as a subsystem providing SuperSpeed USB connectivity to the application processor. Figure 1. EZ-USB FX3 as Main Processor Crystal* Clock USB Host USB Ez-USB FX3 GPIF II External Slave Device (e.g. Image Sensor) I 2C * A clock input may be provided on the CLKIN pin instead of a crystal input Document Number: 001-52136 Rev. *S EEPROM Page 5 of 53 CYUSB301X/CYUSB201X Figure 2. EZ-USB FX3 as a Coprocessor Crystal* Clock USB Host USB Ez-USB FX3 GPIF II External Master (e.g. MCU/CPU/ FPGA/ASIC) I 2C * A clock input may be provided on the CLKIN pin instead of a crystal input EEPROM USB Interface OTG FX3 complies with the following specifications and supports the following features: FX3 is compliant with the OTG Specification Revision 2.0. In OTG mode, FX3 supports both A and B device modes and supports Control, Interrupt, Bulk, and Isochronous data transfers. ■ Supports USB peripheral functionality compliant with USB 3.1 Specification Revision 1.0 and is also backward compatible with the USB 2.0 Specification. ■ FX3 Hi-Speed parts (CYUSB201X) only support USB 2.0. ■ Complies with OTG Supplement Revision 2.0. It supports High-Speed, Full-Speed, and Low-Speed OTG dual-role device capability. As a peripheral, FX3 is capable of SuperSpeed, High-Speed, and Full-Speed. As a host, it is capable of High-Speed, Full-Speed, and Low-Speed. ■ Supports Carkit Pass-Through UART functionality on USB D+/D– lines based on the CEA-936A specification. ■ Supports 16 IN and 16 OUT endpoints. ■ Supports the USB 3.0 Streams feature. It also supports USB Attached SCSI (UAS) device-class to optimize mass-storage access performance. ■ ■ As a USB peripheral, application examples show that the FX3 supports UAS, USB Video Class (UVC), and Mass Storage Class (MSC) USB peripheral classes. All other device classes can be supported by customer firmware; a template example is provided as a starting point. FX3 requires an external charge pump (either standalone or integrated into a PMIC) to power VBUS in the OTG A-device mode. The Target Peripheral List for OTG host implementation consists of MSC- and HID-class devices. FX3 does not support Attach Detection Protocol (ADP). OTG Connectivity In OTG mode, FX3 can be configured to be an A, B, or dual-role device. It can connect to the following: ■ ACA device ■ Targeted USB peripheral ■ SRP-capable USB peripheral ■ HNP-capable USB peripheral ■ OTG host ■ HNP-capable host ■ OTG device As an OTG host, application examples show that FX3 supports MSC and HID device classes. Note When the USB port is not in use, disable the PHY and transceiver to save power. Document Number: 001-52136 Rev. *S Page 6 of 53 CYUSB301X/CYUSB201X ReNumeration Figure 3. System Diagram with OVP Device For VBUS Because of FX3's soft configuration, one chip can take on the identities of multiple distinct USB devices. VIO5 AVDD VDD CVDDQ VIO3 VIO4 VIO2 VBUS OTG_ID OVP device USB Connector 2 SSRXSSRX+ SSTXSSTX+ DD+ 3 4 5 6 7 8 9 USB-Port EZ-Dtect FX3 can detect the following resistance ranges: VIO1 U3RXVDDQ EZ-USB FX3 1 FX3 supports USB Charger and accessory detection (EZ-Dtect). The charger detection mechanism complies with the Battery Charging Specification Revision 1.1. In addition to supporting this version of the specification, FX3 also provides hardware support to detect the resistance values on the ID pin. U3TXVDDQ POWER SUBSYSTEM When first plugged into USB, FX3 enumerates automatically with the Cypress Vendor ID (0x04B4) and downloads firmware and USB descriptors over the USB interface. The downloaded firmware executes an electrical disconnect and connect. FX3 enumerates again, this time as a device defined by the downloaded information. This patented two-step process, called ReNumeration, happens instantly when the device is plugged in. GND ■ Less than 10 ■ Less than 1 k Carkit UART Mode ■ 65 k to 72 k ■ 35 kto 39 k The USB interface supports the Carkit UART mode (UART over D+/D–) for non-USB serial data transfer. This mode is based on the CEA-936A specification. ■ 99.96 k to 104.4 k (102 k2%) ■ 119 k to 132 k ■ Higher than 220 k ■ 431.2 k to 448.8 k (440 k2%) In the Carkit UART mode, the output signaling voltage is 3.3 V. When configured for the Carkit UART mode, TXD of UART (output) is mapped to the D– line, and RXD of UART (input) is mapped to the D+ line. FX3's charger detects a dedicated wall charger, Host/Hub charger, and Host/Hub. VBUS Overvoltage Protection The maximum input voltage on FX3's VBUS pin is 6 V. A charger can supply up to 9 V on VBUS. In this case, an external overvoltage protection (OVP) device is required to protect FX3 from damage on VBUS. Figure 3 shows the system application diagram with an OVP device connected on VBUS. Refer to Table 8 for the operating range of VBUS and VBATT. In the Carkit UART mode, FX3 disables the USB transceiver and D+ and D– pins serve as pass-through pins to connect to the UART of the host processor. The Carkit UART signals may be routed to the GPIF II interface or to GPIO[48] and GPIO[49], as shown in Figure on page 8. In this mode, FX3 supports a rate of up to 9600 bps. Figure 4. Carkit UART Pass-through Block Diagram Ctrl Carkit UART Pass-through UART_ TXD TXD UART_ RXD RXD RXD (DP) Carkit UART Pass-through Interface on GPIOs Document Number: 001-52136 Rev. *S USB PHY DM MUX DP GPIO[48] (UART_ TX) USB-Port ( ) Carkit UART Pass-through Interface on GPIF II TXD (DM) GPIO[49] ( UART_ RX) Page 7 of 53 CYUSB301X/CYUSB201X GPIF II CPU The high-performance GPIF II interface enables functionality similar to, but more advanced than, FX2LP’s GPIF and Slave FIFO interfaces. FX3 has an on-chip 32-bit, 200-MHz ARM926EJ-S core CPU. The core has direct access to 16 KB of Instruction Tightly Coupled Memory (TCM) and 8 KB of Data TCM. The ARM926EJ-S core provides a JTAG interface for firmware debugging. The GPIF II is a programmable state machine that enables a flexible interface that may function either as a master or slave in industry-standard or proprietary interfaces. Both parallel and serial interfaces may be implemented with GPIF II. Here is a list of GPIF II features: ■ Functions as master or slave ■ Provides 256 firmware programmable states ■ Supports 8-bit, 16-bit, 24-bit, and 32-bit parallel data bus ■ Enables interface frequencies up to 100 MHz ■ Supports 14 configurable control pins when a 32- bit data bus is used. All control pins can be either input/output or bidirectional. ■ Supports 16 configurable control pins when a 16/8 data bus is used. All control pins can be either input/output or bi-directional. GPIF II state transitions are based on control input signals. The control output signals are driven as a result of the GPIF II state transitions. The INT# output signal can be controlled by GPIF II. Refer to the GPIFII Designer tool. The GPIF II state machine’s behavior is defined by a GPIF II descriptor. The GPIF II descriptor is designed such that the required interface specifications are met. 8 KB of memory (separate from the 256/512 KB of embedded SRAM) is dedicated to the GPIF II waveform where the GPIF II descriptor is stored in a specific format. Cypress’s GPIFII Designer Tool enables fast development of GPIF II descriptors and includes examples for common interfaces. Example implementations of GPIF II are the asynchronous slave FIFO and synchronous slave FIFO interfaces. Slave FIFO interface The Slave FIFO interface signals are shown in Figure 5. This interface allows an external processor to directly access up to four buffers internal to FX3. Further details of the Slave FIFO interface are described on page 24. Note Access to all 32 buffers is also supported over the slave FIFO interface. For details, contact Cypress Applications Support. Figure 5. Slave FIFO Interface P KTEND FLAG B FLAG A A [1:0] D[31:0] ■ Integrates 256/512 KB of embedded SRAM for code and data and 8 KB of Instruction cache and Data cache. ■ Implements efficient and flexible DMA connectivity between the various peripherals (such as, USB, GPIF II, I2S, SPI, UART, I2C), requiring firmware only to configure data accesses between peripherals, which are then managed by the DMA fabric. ■ Allows easy application development using industry-standard development tools for ARM926EJ-S. Examples of the FX3 firmware are available with the Cypress EZ-USB FX3 Development Kit. JTAG Interface FX3’s JTAG interface has a standard five-pin interface to connect to a JTAG debugger in order to debug firmware through the CPU-core's on-chip-debug circuitry. Industry-standard debugging tools for the ARM926EJ-S core can be used for the FX3 application development. Other Interfaces FX3 supports the following serial peripherals: ■ SPI ■ UART ■ I2C ■ I2S The SPI, UART, and I2S interfaces are multiplexed on the serial peripheral port. The CYUSB3012 and CYUSB3014 Pin List on page 15 shows details of how these interfaces are multiplexed. Note that when GPIF II is configured for a 32-bit data bus width (CYUSB3012 and CYUSB3014), then the SPI interface is not available. SPI Interface FX3 supports an SPI Master interface on the Serial Peripherals port. The maximum operation frequency is 33 MHz. S LCS# External M aster (For exam ple, M C U/C PU/ FPG A/ASIC ) FX3 offers the following advantages: EZ-U SB FX3 The SPI controller supports four modes of SPI communication (see SPI Timing Specification on page 40 for details on the modes) with the Start-Stop clock. This controller is a single-master controller with a single automated SSN control. It supports transaction sizes ranging from four bits to 32 bits. S LW R# SLRD# S LO E# Note: M ultiple Flags m ay be configured. Document Number: 001-52136 Rev. *S Page 8 of 53 CYUSB301X/CYUSB201X Boot Options UART Interface The UART interface of FX3 supports full-duplex communication. It includes the signals noted in Table 1. Table 1. UART Interface Signals Signal TX RX CTS RTS Description Output signal Input signal Flow control Flow control The UART is capable of generating a range of baud rates, from 300 bps to 4608 Kbps, selectable by the firmware. If flow control is enabled, then FX3's UART only transmits data when the CTS input is asserted. In addition to this, FX3’s UART asserts the RTS output signal, when it is ready to receive data. FX3 can load boot images from various sources, selected by the configuration of the PMODE pins. Following are the FX3 boot options: ■ Boot from USB ■ Boot from I2C ■ Boot from SPI (SPI devices supported are M25P32 (32 Mbit), M25P16 (16 Mbit), M25P80 (8 Mbit), and M25P40 (4 Mbit)) or their equivalents ■ Boot from GPIF II ASync ADMux mode ■ Boot from GPIF II Sync ADMux mode ■ Boot from GPIF II ASync SRAM mode Table 2. FX3 Booting Options 2 PMODE[2:0][1] F00 F01 F11 F0F F1F 1FF 0F1 I C Interface I2C I2C FX3’s interface is compatible with the Bus Specification Revision 3. This I2C interface is capable of operating only as I2C master; therefore, it may be used to communicate with other I2C slave devices. For example, FX3 may boot from an EEPROM connected to the I2C interface, as a selectable boot option. FX3’s I2C Master Controller also supports multi-master mode functionality. The power supply for the I2C interface is VIO5, which is a separate power domain from the other serial peripherals. This gives the I2C interface the flexibility to operate at a different voltage than the other serial interfaces. The I2C controller supports bus frequencies of 100 kHz, 400 kHz, and 1 MHz. When VIO5 is 1.2 V, the maximum operating frequency supported is 100 kHz. When VIO5 is 1.8 V, 2.5 V, or 3.3 V, the operating frequencies supported are 400 kHz and 1 MHz. The I2C controller supports clock-stretching to enable slower devices to exercise flow control. Boot From Sync ADMux (16-bit) Async ADMux (16-bit) USB boot Async SRAM (16-bit) I2C, On Failure, USB Boot is Enabled I2C only SPI, On Failure, USB Boot is Enabled Reset Hard Reset The I2C interface’s SCL and SDA signals require external pull-up resistors. The pull-up resistors must be connected to VIO5. A hard reset is initiated by asserting the Reset# pin on FX3. The specific reset sequence and timing requirements are detailed in Figure 30 on page 42 and Table 19 on page 42. All I/Os are tristated during a hard reset. Note however, that the on-chip bootloader has control after a hard reset and it will configure I/O signals depending on the selected boot mode; see AN76405 EZ-USB® FX3™ Boot Options for more details. I2S Interface Soft Reset FX3 has an I2S port to support external audio codec devices. FX3 functions as I2S Master as transmitter only. The I2S interface consists of four signals: clock line (I2S_CLK), serial data line (I2S_SD), word select line (I2S_WS), and master system clock (I2S_MCLK). FX3 can generate the system clock as an output on I2S_MCLK or accept an external system clock input on I2S_MCLK. In a soft reset, the processor sets the appropriate bits in the PP_INIT control register. There are two types of Soft Reset: The sampling frequencies supported by the I2S interface are 32 kHz, 44.1 kHz, and 48 kHz. ■ CPU Reset – The CPU Program Counter is reset. Firmware does not need to be reloaded following a CPU Reset. ■ Whole Device Reset – This reset is identical to Hard Reset. ■ The firmware must be reloaded following a Whole Device Reset. Note 1. F indicates Floating. Document Number: 001-52136 Rev. *S Page 9 of 53 CYUSB301X/CYUSB201X Clocking Clock inputs to FX3 must meet the phase noise and jitter requirements specified in Table 4 on page 10. FX3 allows either a crystal to be connected between the XTALIN and XTALOUT pins or an external clock to be connected at the CLKIN pin. The XTALIN, XTALOUT, CLKIN, and CLKIN_32 pins can be left unconnected if they are not used. The input clock frequency is independent of the clock and data rate of the FX3 core or any of the device interfaces. The internal PLL applies the appropriate clock multiply option depending on the input frequency. Crystal frequency supported is 19.2 MHz, while the external clock frequencies supported are 19.2, 26, 38.4, and 52 MHz. Table 3. Crystal/Clock Frequency Selection FX3 has an on-chip oscillator circuit that uses an external 19.2-MHz (±100 ppm) crystal (when the crystal option is used). An appropriate load capacitance is required with a crystal. Refer to the specification of the crystal used to determine the appropriate load capacitance. The FSLC[2:0] pins must be configured appropriately to select the crystal- or clock-frequency option. The configuration options are shown in Table 3. FSLC[2] FSLC[1] FSLC[0] 0 1 1 1 1 0 0 0 1 1 0 0 1 0 1 Crystal/Clock Frequency 19.2-MHz crystal 19.2-MHz input CLK 26-MHz input CLK 38.4-MHz input CLK 52-MHz input CLK Table 4. FX3 Input Clock Specifications Parameter Phase noise Description 100-Hz offset 1-kHz offset 10-kHz offset 100-kHz offset 1-MHz offset Maximum frequency deviation Duty cycle Overshoot Undershoot Rise time/fall time – – – – – Specification Min – – – – – – 30 – – – Units Max –75 –104 –120 –128 –130 150 70 3 –3 3 dB ppm % ns 32-kHz Watchdog Timer Clock Input FX3 includes a watchdog timer. The watchdog timer can be used to interrupt the ARM926EJ-S core, automatically wake up the FX3 in Standby mode, and reset the ARM926EJ-S core. The watchdog timer runs a 32-kHz clock, which may be optionally supplied from an external source on a dedicated FX3 pin. The firmware can disable the watchdog timer. Requirements for the optional 32-kHz clock input are listed in Table 5. Table 5. 32-kHz Clock Input Requirements Min Max Units Duty cycle Parameter 40 60 % Frequency deviation – ±200 ppm Rise time/fall time – 200 ns Document Number: 001-52136 Rev. *S Page 10 of 53 CYUSB301X/CYUSB201X Power ■ FX3 has the following power supply domains: ■ IO_VDDQ: This is a group of independent supply domains for digital I/Os. The voltage level on these supplies is 1.8 V to 3.3 V. FX3 provides six independent supply domains for digital I/Os listed as follows (see Table 7 on page 15 for details on each of the power domain signals): ❐ VIO1: GPIF II I/O ❐ VIO2: IO2 ❐ VIO3: IO3 2 ❐ VIO4: UART-/SPI/I S 2 ❐ VIO5: I C and JTAG (supports 1.2 V to 3.3 V) ❐ CVDDQ: This is the supply voltage for clock and reset I/O. It should be either 1.8 V or 3.3 V based on the voltage level of the CLKIN signal. ❐ VDD: This is the supply voltage for the logic core. The nominal supply-voltage level is 1.2 V. This supplies the core logic circuits. The same supply must also be used for the following: • AVDD: This is the 1.2-V supply for the PLL, crystal oscillator, and other core analog circuits • U3TXVDDQ/U3RXVDDQ: These are the 1.2-V supply voltages for the USB 3.0 interface. VBATT/VBUS: This is the 3.2-V to 6-V battery power supply for the USB I/O and analog circuits. This supply powers the USB transceiver through FX3's internal voltage regulator. VBATT is internally regulated to 3.3 V. Power Modes FX3 supports the following power modes: ■ Normal mode: This is the full-functional operating mode. The internal CPU clock and the internal PLLs are enabled in this mode. ❐ Normal operating power consumption does not exceed the sum of ICC Core max and ICC USB max (see Table 7 on page 15 for current consumption specifications). ❐ The I/O power supplies VIO2, VIO3, VIO4, and VIO5 can be turned off when the corresponding interface is not in use. VIO1 cannot be turned off at any time if the GPIF II interface is used in the application. ■ Low-power modes (see Table 6 on page 11): ❐ Suspend mode with USB 3.0 PHY enabled (L1) ❐ Suspend mode with USB 3.0 PHY disabled (L2) ❐ Standby mode (L3) ❐ Core power-down mode (L4) Table 6. Entry and Exit Methods for Low-Power Modes Low-Power Mode Suspend Mode with USB 3.0 PHY Enabled (L1) Characteristics ■ The power consumption in this mode does not exceed ISB1 ■ USB 3.0 PHY is enabled and is in U3 mode (one of the suspend modes defined by the USB 3.0 specification). This one block alone is operational with its internal clock while all other clocks are shut down ■ All I/Os maintain their previous state ■ Power supply for the wakeup source and core power must be retained. All other power domains can be turned on/off individually ■ ■ ■ The states of the configuration registers, buffer memory, and all internal RAM are maintained All transactions must be completed before FX3 enters Suspend mode (state of outstanding transactions are not preserved) Methods of Entry ■ ■ Firmware executing on ARM926EJ-S core can put FX3 into suspend mode. For example, on USB suspend condition, firmware may decide to put FX3 into suspend mode External Processor, through the use of mailbox registers, can put FX3 into suspend mode Methods of Exit ■ D+ transitioning to low or high ■ D- transitioning to low or high ■ Impedance change on OTG_ID pin ■ Resume condition on SSRX± ■ Detection of VBUS ■ Level detect on UART_CTS (programmable polarity) ■ GPIF II interface assertion of CTL[0] ■ Assertion of RESET# The firmware resumes operation from where it was suspended (except when woken up by RESET# assertion) because the program counter does not reset Document Number: 001-52136 Rev. *S Page 11 of 53 CYUSB301X/CYUSB201X Table 6. Entry and Exit Methods for Low-Power Modes (continued) Low-Power Mode Suspend Mode with USB 3.0 PHY Disabled (L2) Standby Mode (L3) Characteristics ■ The power consumption in this mode does not exceed ISB2 ■ USB 3.0 PHY is disabled and the USB interface is in suspend mode ■ The clocks are shut off. The PLLs are disabled ■ All I/Os maintain their previous state ■ USB interface maintains the previous state Methods of Entry ■ ■ Firmware executing on ARM926EJ-S core can put FX3 into suspend mode. For example, on USB suspend condition, firmware may decide to put FX3 into suspend mode External Processor, through the use of mailbox registers can put FX3 into suspend mode Methods of Exit ■ D+ transitioning to low or high ■ D- transitioning to low or high ■ Impedance change on OTG_ID pin ■ Resume condition on SSRX± ■ Detection of VBUS ■ Power supply for the wakeup source and core power must be retained. All other power domains can be turned on/off individually ■ Level detect on UART_CTS (programmable polarity) ■ The states of the configuration registers, buffer memory and all internal RAM are maintained ■ GPIF II interface assertion of CTL[0] ■ Assertion of RESET# ■ All transactions must be completed before FX3 enters Suspend mode (state of outstanding transactions are not preserved) ■ The firmware resumes operation from where it was suspended (except when woken up by RESET# assertion) because the program counter does not reset ■ The power consumption in this mode does not exceed ISB3 ■ Detection of VBUS ■ ■ All configuration register settings and program/data RAM contents are preserved. However, data in the buffers or other parts of the data path, if any, is not guaranteed. Therefore, the external processor should take care that the data needed is read before putting FX3 into this Standby Mode Level detect on UART_CTS (Programmable Polarity) ■ GPIF II interface assertion of CTL[0] ■ Assertion of RESET# ■ The program counter is reset after waking up from Standby ■ GPIO pins maintain their configuration ■ Crystal oscillator is turned off ■ Internal PLL is turned off ■ USB transceiver is turned off ■ ARM926EJ-S core is powered down. Upon wakeup, the core re-starts and runs the program stored in the program/data RAM ■ Power supply for the wakeup source and core power must be retained. All other power domains can be turned on/off individually Document Number: 001-52136 Rev. *S ■ Firmware executing on ARM926EJ-S core or external processor configures the appropriate register Page 12 of 53 CYUSB301X/CYUSB201X Table 6. Entry and Exit Methods for Low-Power Modes (continued) Low-Power Mode Core Power Down Mode (L4) Characteristics ■ The power consumption in this mode does not exceed ISB4 ■ Core power is turned off ■ All buffer memory, configuration registers, and the program RAM do not maintain state. After exiting this mode, reload the firmware ■ In this mode, all other power domains can be turned on/off individually Methods of Entry ■ Turn off VDD Methods of Exit ■ Reapply VDD ■ Assertion of RESET# Digital I/Os EMI FX3 has internal firmware-controlled pull-up or pull-down resistors on all digital I/O pins. An internal 50-k resistor pulls the pins high, while an internal 10-k resistor pulls the pins low to prevent them from floating. The I/O pins may have the following states: FX3 meets EMI requirements outlined by FCC 15B (USA) and EN55022 (Europe) for consumer electronics. FX3 can tolerate EMI, conducted by the aggressor, outlined by these specifications and continue to function as expected. System-level ESD ■ Tristated (High-Z) ■ Weak pull-up (via internal 50 k) ■ Pull-down (via internal 10 k) FX3 has built-in ESD protection on the D+, D–, and GND pins on the USB interface. The ESD protection levels provided on these ports are: ■ Hold (I/O hold its value) when in low-power modes ■ ■ The JTAG TDI, TMS, and TRST# signals have fixed 50-k internal pull-ups, and the TCK signal has a fixed 10-k pull-down resistor. ±2.2-kV human body model (HBM) based on JESD22-A114 Specification ■ ±6-kV contact discharge and ±8-kV air gap discharge based on IEC61000-4-2 level 3A ■ ± 8-kV Contact Discharge and ±15-kV Air Gap Discharge based on IEC61000-4-2 level 4C. All unused I/Os should be pulled high by using the internal pull-up resistors. All unused outputs should be left floating. All I/Os can be driven at full-strength, three-quarter strength, half-strength, or quarter-strength. These drive strengths are configured separately for each interface. GPIOs This protection ensures the device continues to function after ESD events up to the levels stated in this section. The SSRX+, SSRX–, SSTX+, and SSTX– pins only have up to ±2.2-kV HBM internal ESD protection. EZ-USB enables a flexible pin configuration both on the GPIF II and the serial peripheral interfaces. Any unused control pins (except CTL[15]) on the GPIF II interface can be used as GPIOs. Similarly, any unused pins on the serial peripheral interfaces may be configured as GPIOs. See Pin Configurations for pin configuration options. All GPIF II and GPIO pins support an external load of up to 16 pF for every pin. Document Number: 001-52136 Rev. *S Page 13 of 53 CYUSB301X/CYUSB201X Pin Configurations Figure 6. FX3 121-ball BGA Ball Map (Top View) 1 2 3 4 5 6 7 8 9 10 11 A U3VSSQ U3RXVDDQ SSRXM SSRXP SSTXP SSTXM AVDD VSS DP DM NC B VIO4 FSLC[0] R_USB3 FSLC[1] U3TXVDDQ CVDDQ AVSS VSS VSS VDD TRST# C GPIO[54] GPIO[55] VDD GPIO[57] RESET# XTALIN XTALOUT R_USB2 OTG_ID TDO D GPIO[50] GPIO[51] GPIO[52] GPIO[53] GPIO[56] CLKIN_32 CLKIN VSS E GPIO[47] VSS VIO3 GPIO[49] GPIO[48] FSLC[2] TDI TMS F VIO2 GPIO[45] GPIO[44] GPIO[41] GPIO[46] TCK GPIO[2] G VSS GPIO[42] GPIO[43] GPIO[30] GPIO[25] GPIO[22] GPIO[21] H VDD GPIO[39] GPIO[40] GPIO[31] GPIO[29] GPIO[26] GPIO[20] J GPIO[38] GPIO[36] GPIO[37] GPIO[34] GPIO[28] GPIO[16] K GPIO[35] GPIO[33] VSS VSS GPIO[27] L VSS VSS VSS GPIO[32] VDD I2C_GPIO[58] I2C_GPIO[59] VIO5 O[60] VDD VBATT VBUS GPIO[5] GPIO[1] GPIO[0] VDD GPIO[15] GPIO[4] GPIO[3] VSS GPIO[24] GPIO[7] GPIO[6] VIO1 GPIO[19] GPIO[14] GPIO[9] GPIO[8] VDD GPIO[23] GPIO[18] GPIO[17] GPIO[13] GPIO[12] GPIO[10] VSS VDD INT# VIO1 GPIO[11] VSS Figure 7. FX3 131-Ball WLCSP Ball Map (Bottom View) 12 11 10 A VSS VSS SSRXM B GPIO[55] VIO4 SSRXP GPIO[56] VIO3 GPIO[49] GPIO[50] C D 9 8 7 6 5 4 3 2 1 SSTXM FSLC[0] AVSS AVDD DP VSS DM VDD R_USB3 SSTXP FSLC[2] XTALIN XTALOUT NC R_USB2 NC VDD U3RXVDDQ U3VSSQ U3TXVDDQ CVDDQ CLKIN_32 CLKIN VSS OTG_ID TDO TRST# GPIO[53] GPIO[54] RESET# VDD I2C_GPIO[58 ] TMS VIO5 TCK I2C_GPIO[59 ] VSS E GPIO[57] GPIO[48] GPIO[51] GPIO[52] O[60] VSS VSS VSS VSS GPIO[3] VBATT VBUS F VSS GPIO[46] GPIO[47] FSLC[1] TDI VDD VDD VDD VDD GPIO[4] GPIO[1] GPIO[0] G VIO2 GPIO[43] GPIO[44] GPIO[45] VSS VSS VDD VSS GPIO[9] GPIO[7] GPIO[6] GPIO[2] H VSS GPIO[40] GPIO[41] GPIO[42] GPIO[39] VSS GPIO[20] GPIO[18] GPIO[14] GPIO[12] GPIO[8] VIO1 J VIO2 GPIO[38] GPIO[37] GPIO[36] GPIO[31] GPIO[27] GPIO[25] GPIO[22] GPIO[19] GPIO[15] GPIO[10] GPIO[5] K GPIO[35] GPIO[34] GPIO[33] GPIO[32] GPIO[28] GPIO[26] GPIO[16] GPIO[21] INT# GPIO[24] GPIO[11] VSS L VDD VSS VDD GPIO[30] GPIO[29] VIO1 GPIO[23] VSS VIO1 GPIO[17] GPIO[13] VSS Note No ball is populated at location A9. Figure 8. FX3 Hi-Speed 121-Ball BGA Ball Map (Top View) A 1 2 3 4 5 6 7 8 9 10 11 U3VSSQ VDD NC NC NC NC AVDD VSS DP DM NC TRST# B VIO4 FSLC[0] NC FSLC[ 1] VDD CVDDQ AVSS VSS VSS VDD C GPIO[ 54] GPIO[55] VDD GPIO[57] RESET# XTALIN XTALOUT R_USB2 OTG_ID TDO D GPIO[ 50] GPIO[ 51] GPIO[ 52] GPIO[53] GPIO[ 56] CLKIN_32 CLKIN VSS E GPIO[ 47] VSS VIO3 GPIO[ 49] GPIO[ 48] FSLC[ 2] TDI TM S VDD VBATT VBUS F VIO2 GPIO[45] GPIO[44] GPIO[41] GPIO[ 46] TCK GPIO[ 2] GPIO[5] GPIO[ 1] GPIO[0] VDD G VSS GPIO[ 42] GPIO[43] GPIO[ 30] GPIO[ 25] GPIO[22] GPIO[ 21] GPIO[15] GPIO[4] GPIO[3] VSS H VDD GPIO[ 39] GPIO[40] GPIO[31] GPIO[ 29] GPIO[26] GPIO[20] GPIO[ 24] GPIO[7] GPIO[6] VIO1 J GPIO[38] GPIO[ 36] GPIO[ 37] GPIO[ 34] GPIO[ 28] GPIO[ 16] GPIO[ 19] GPIO[14] GPIO[9] GPIO[8] VDD K GPIO[ 35] GPIO[ 33] VSS VSS GPIO[ 27] GPIO[23] GPIO[ 18] GPIO[17] GPIO[13] GPIO[12] GPIO[ 10] L VSS VSS VSS GPIO[ 32] VDD VSS VDD INT# VIO1 GPIO[ 11] VSS Document Number: 001-52136 Rev. *S I2C_GPIO[ 58] I2C_GPIO[ 59] VIO5 O[ 60] Page 14 of 53 CYUSB301X/CYUSB201X Pin Description Table 7. CYUSB3012 and CYUSB3014 Pin List BGA WLCSP Power Domain I/O Name F10 F1 VIO1 I/O GPIO[0] DQ[0] DQ[0] F9 F2 VIO1 I/O GPIO[1] DQ[1] DQ[1] Description GPIF II Interface Slave FIFO Interface F7 G1 VIO1 I/O GPIO[2] DQ[2] DQ[2] G10 E3 VIO1 I/O GPIO[3] DQ[3] DQ[3] G9 F3 VIO1 I/O GPIO[4] DQ[4] DQ[4] F8 J1 VIO1 I/O GPIO[5] DQ[5] DQ[5] H10 G2 VIO1 I/O GPIO[6] DQ[6] DQ[6] H9 G3 VIO1 I/O GPIO[7] DQ[7] DQ[7] J10 H2 VIO1 I/O GPIO[8] DQ[8] DQ[8] J9 G4 VIO1 I/O GPIO[9] DQ[9] DQ[9] K11 J2 VIO1 I/O GPIO[10] DQ[10] DQ[10] L10 K2 VIO1 I/O GPIO[11] DQ[11] DQ[11] K10 H3 VIO1 I/O GPIO[12] DQ[12] DQ[12] K9 L2 VIO1 I/O GPIO[13] DQ[13] DQ[13] J8 H4 VIO1 I/O GPIO[14] DQ[14] DQ[14] DQ[15] G8 J3 VIO1 I/O GPIO[15] DQ[15] J6 K6 VIO1 I/O GPIO[16] PCLK CLK K8 L3 VIO1 I/O GPIO[17] CTL[0] SLCS# K7 H5 VIO1 I/O GPIO[18] CTL[1] SLWR# J7 J4 VIO1 I/O GPIO[19] CTL[2] SLOE# H7 H6 VIO1 I/O GPIO[20] CTL[3] SLRD# G7 K5 VIO1 I/O GPIO[21] CTL[4] FLAGA G6 J5 VIO1 I/O GPIO[22] CTL[5] FLAGB K6 L6 VIO1 I/O GPIO[23] CTL[6] GPIO H8 K3 VIO1 I/O GPIO[24] CTL[7] PKTEND# G5 J6 VIO1 I/O GPIO[25] CTL[8] GPIO H6 K7 VIO1 I/O GPIO[26] CTL[9] GPIO K5 J7 VIO1 I/O GPIO[27] CTL[10] GPIO A1 J5 K8 VIO1 I/O GPIO[28] CTL[11] H5 L8 VIO1 I/O GPIO[29] CTL[12] A0 G4 L9 VIO1 I/O GPIO[30] PMODE[0] PMODE[0] H4 J8 VIO1 I/O GPIO[31] PMODE[1] PMODE[1] L4 K9 VIO1 I/O GPIO[32] PMODE[2] PMODE[2] L8 K4 VIO1 I/O INT# INT#/CTL[15] CTL[15] K2 32-bit Data Bus 16 - bit Data Bus + UART+SPI+I2S 16 - bit Data Bus + UART+GPIO GPIO GPIO K10 VIO2 I/O GPIO[33] DQ[16] 16 - bit 16 - bit Data Data Bus + Bus + SPI+GPIO I2S+GPIO GPIO GPIO GPIO only GPIO J4 K11 VIO2 I/O GPIO[34] DQ[17] GPIO GPIO GPIO GPIO GPIO K1 K12 VIO2 I/O GPIO[35] DQ[18] GPIO GPIO GPIO GPIO GPIO J2 J9 VIO2 I/O GPIO[36] DQ[19] GPIO GPIO GPIO GPIO GPIO J3 J10 VIO2 I/O GPIO[37] DQ[20] GPIO GPIO GPIO GPIO GPIO Document Number: 001-52136 Rev. *S Page 15 of 53 CYUSB301X/CYUSB201X Table 7. CYUSB3012 and CYUSB3014 Pin List (continued) BGA WLCSP Power Domain I/O Name Description J1 J11 VIO2 I/O GPIO[38] DQ[21] GPIO GPIO GPIO GPIO H2 H8 VIO2 I/O GPIO[39] DQ[22] GPIO GPIO GPIO GPIO GPIO GPIO H3 H11 VIO2 I/O GPIO[40] DQ[23] GPIO GPIO GPIO GPIO GPIO F4 H10 VIO2 I/O GPIO[41] DQ[24] GPIO GPIO GPIO GPIO GPIO G2 H9 VIO2 I/O GPIO[42] DQ[25] GPIO GPIO GPIO GPIO GPIO G3 G11 VIO2 I/O GPIO[43] DQ[26] GPIO GPIO GPIO GPIO GPIO F3 G10 VIO2 I/O GPIO[44] DQ[27] GPIO GPIO GPIO GPIO GPIO F2 G09 VIO2 I/O GPIO[45] GPIO GPIO GPIO GPIO GPIO GPIO GPIO F5 F11 VIO3 I/O GPIO[46] DQ[28] UART_RT S GPIO GPIO GPIO E1 F10 VIO3 I/O GPIO[47] DQ[29] UART_CT S GPIO GPIO GPIO GPIO E5 E11 VIO3 I/O GPIO[48] DQ[30] UART_TX GPIO GPIO GPIO GPIO E4 D12 VIO3 I/O GPIO[49] DQ[31] UART_R X GPIO GPIO GPIO GPIO D1 D11 VIO3 I/O GPIO[50] I2S_CLK I2S_CLK GPIO GPIO GPIO GPIO D2 E10 VIO3 I/O GPIO[51] I2S_SD I2S_SD GPIO GPIO GPIO GPIO D3 E9 VIO3 I/O GPIO[52] I2S_WS I2S_WS GPIO GPIO GPIO GPIO D4 D10 VIO4 I/O GPIO[53] UART_RTS SPI_SCK UART_RTS SPI_SCK GPIO GPIO C1 D9 VIO4 I/O GPIO[54] UART_CTS SPI_SSN UART_CTS SPI_SSN I2S_CLK GPIO C2 B12 VIO4 I/O GPIO[55] UART_TX SPI_MIS O UART_TX SPI_MISO I2S_SD GPIO D5 C12 VIO4 I/O GPIO[56] UART_RX SPI_MOS I UART_RX SPI_MOSI I2S_WS GPIO C4 E12 VIO4 I/O GPIO[57] I2S_MCLK I2S_MCL K GPIO GPIO I2S_MCL K GPIO USB Port CYUSB301X CYUSB201X A3 A10 U3RXVD DQ I SSRXM SSRX- NC A4 B10 U3RXVD DQ I SSRXP SSRX+ NC A6 A8 U3TXVD DQ O SSTXM SSTX- NC A5 B8 U3TXVD DQ O SSTXP SSTX+ NC B3 B9 U3TXVD DQ I/O R_usb3 Precision resistor for USB 3.0 (Connect a 200 ±1% resistor between this pin and GND) NC C9 C3 VBUS/ VBATT I OTG_ID OTG_ID A9 A4 VBUS/V BATT I/O DP D+ A10 A2 VBUS/V BATT I/O DM D– C8 B3 VBUS/VBAT T I/O R_usb2 Precision resistor for USB 2.0 (Connect a 6.04 k ±1% resistor between this pin and GND) Clock and Reset B2 A7 CVDDQ I FSLC[0] C6 B6 AVDD I/O XTALIN FSLC[0] XTALIN C7 B5 AVDD I/O XTALOUT XTALOUT B4 F9 CVDDQ I FSLC[1] FSLC[1] E6 B7 CVDDQ I FSLC[2] FSLC[2] D7 C5 CVDDQ I CLKIN CLKIN Document Number: 001-52136 Rev. *S Page 16 of 53 CYUSB301X/CYUSB201X Table 7. CYUSB3012 and CYUSB3014 Pin List (continued) BGA WLCSP Power Domain I/O Name Description CLKIN_32 D6 C6 CVDDQ I CLKIN_32 C5 D8 CVDDQ I RESET# RESET# I2C and JTAG D9 D6 VIO5 I/O I2C_GPIO[58 ] I2C_SCL D10 D2 VIO5 I/O I2C_GPIO[59 ] I2C_SDA E7 F8 VIO5 I TDI TDI C10 C2 VIO5 O TDO TDO B11 C1 VIO5 I TRST# TRST# E8 D5 VIO5 I TMS TMS F6 D3 VIO5 I TCK TCK D11 E8 VIO5 O O[60] Charger detect output E10 E2 PWR VBATT B10 B1 PWR VDD – A1 A1 C9 – – – – – – – – – – – – – – – – – – – – – – – – – – – – – – Power E11 E1 D8 C4 H11 H1 E2 K1 L9 L4 G1 L5 – – L7 L1 F1 J12 G11 H12 G12 E3 C11 L1 F12 B1 B11 L6 A11 – A12 B6 C7 B5 C8 A2 C10 C11 D4 L11 A3 A7 A5 B7 A6 C3 F4 B8 D1 E9 F5 PWR VDD PWR U3VSSQ PWR VBUS PWR VSS PWR VIO1 PWR VSS PWR VIO1 PWR VSS PWR VIO1 PWR VSS PWR VIO2 PWR VSS PWR VIO2 PWR VIO3 PWR VSS PWR VIO4 PWR VSS PWR VSS PWR CVDDQ PWR U3TXVDDQ PWR U3RXVDDQ PWR VIO5 PWR VSS PWR AVDD PWR AVSS PWR VDD PWR VSS PWR VDD Document Number: 001-52136 Rev. *S – – – – – – – – – – – – – – – – – – – – – – – – – – – – – – Page 17 of 53 CYUSB301X/CYUSB201X Table 7. CYUSB3012 and CYUSB3014 Pin List (continued) BGA WLCSP Power Domain I/O – – – – – – – – – – – – – – – – – B9 E4 F11 F6 – – – – E5 H1 G6 L7 D7 J11 L10 L5 L12 K4 H7 F7 E6 E7 L3 G7 K3 L11 L2 G8 A8 G5 – B4 A11 B2 Name Description PWR VSS PWR VDD – – PWR VSS GND PWR VDD – PWR VSS GND PWR VSS GND PWR VDD PWR VDD PWR VDD PWR VDD PWR VSS – – – – – PWR VSS PWR VSS PWR VSS PWR VSS – – – – – – NC No Connect NC No Connect Document Number: 001-52136 Rev. *S Page 18 of 53 CYUSB301X/CYUSB201X Electrical Specifications ■ Additional ESD protection levels on D+, D–, and GND pins, and serial peripheral pins ■ Exceeding maximum ratings may shorten the useful life of the device. ± 6-kV contact discharge, ± 8-kV air gap discharge based on IEC61000-4-2 level 3A, ± 8-kV contact discharge, and ± 15-kV air gap discharge based on IEC61000-4-2 level 4C Storage temperature .................................... –65 °C to +150 °C Latch-up current .........................................................> 200 mA Ambient temperature with power supplied (Industrial) ............................ –40 °C to +85 °C Maximum output short-circuit current for all I/Os (cumulative).......... ........................................................ –100 mA Ambient temperature with power supplied (Commercial) ............................. 0 °C to +70 °C Maximum output current per I/O (source or sink).......................... ...................................... 20 mA Supply voltage to ground potential VDD, AVDDQ ......................................................................1.25 V Operating Conditions Absolute Maximum Ratings VIO1,VIO2, VIO3, VIO4, VIO5 ............................................. ...3.6 V U3TXVDDQ, U3RXVDDQ .............................................. .....1.25 V DC input voltage to any input pin ........................... .VCC + 0.3 V TA (ambient temperature under bias) Industrial ........................................................ –40 °C to +85 °C Commercial ....................................................... 0 °C to +70 °C VDD, AVDDQ, U3TXVDDQ, U3RXVDDQ DC voltage applied to outputs in high Z state ............................................ VCC + 0.3 V Supply voltage ..................................................1.15 V to 1.25 V (VCC is the corresponding I/O voltage) VBATT supply voltage ...............................................3.2 V to 6 V Static discharge voltage ESD protection levels: VIO1, VIO2, VIO3, VIO4, CVDDQ ■ Supply voltage ......................................................1.7 V to 3.6 V ± 2.2-kV HBM based on JESD22-A114 VIO5 supply voltage ............................................ 1.15 V to 3.6 V DC Specifications Table 8. DC Specifications Parameter Description Min Max Units Notes VDD Core voltage supply 1.15 1.25 V 1.2-V typical AVDD Analog voltage supply 1.15 1.25 V 1.2-V typical VIO1 GPIF II I/O power supply domain 1.7 3.6 V 1.8-, 2.5-, and 3.3-V typical VIO2 IO2 power supply domain 1.7 3.6 V 1.8-, 2.5-, and 3.3-V typical VIO3 IO3 power supply domain 1.7 3.6 V 1.8-, 2.5-, and 3.3-V typical VIO4 UART/SPI/I2S power supply domain 1.7 3.6 V 1.8-, 2.5-, and 3.3-V typical VBATT USB voltage supply 3.2 6 V 3.7-V typical VBUS USB voltage supply 4.0 6 V 5-V typical U3TXVDDQ USB 3.0 1.2-V supply 1.15 1.25 V 1.2-V typical. A 22-µF bypass capacitor is required on this power supply. N/A for CYUSB201X U3RXVDDQ USB 3.0 1.2-V supply 1.15 1.25 V 1.2-V typical. A 22-µF bypass capacitor is required on this power supply. N/A for CYUSB201X CVDDQ Clock voltage supply 1.7 3.6 V 1.8-, 3.3-V typical VIO5 I2C and JTAG voltage supply 1.15 3.6 V 1.2-, 1.8-, 2.5-, and 3.3-V typical VIH1 Input HIGH voltage 1 0.625 × VCC VCC + 0.3 V For 2.0 V VCC 3.6 V (except USB port). VCC is the corresponding I/O voltage supply. VIH2 Input HIGH voltage 2 VCC – 0.4 VCC + 0.3 V For 1.7 V VCC 2.0 V (except USB port). VCC is the corresponding I/O voltage supply. VIL Input LOW voltage V VCC is the corresponding I/O voltage supply. Document Number: 001-52136 Rev. *S –0.3 0.25 × VCC Page 19 of 53 CYUSB301X/CYUSB201X Table 8. DC Specifications (continued) Parameter Description Min Max Units Notes VOH Output HIGH voltage 0.9 × VCC – V IOH (max) = –100 µA tested at quarter drive strength. VCC is the corresponding I/O voltage supply. VOL Output LOW voltage – 0.1 × VCC V IOL (min) = +100 µA tested at quarter drive strength. VCC is the corresponding I/O voltage supply. IIX Input leakage current for all pins except SSTXP/SSXM/SSRXP/SSRXM –1 1 µA All I/O signals held at VDDQ (For I/Os with a pull-up or pull-down resistor connected, the leakage current increases by VDDQ/Rpu or VDDQ/RPD IOZ Output High-Z leakage current for all pins except SSTXP/ SSXM/ SSRXP/SSRXM –1 1 µA All I/O signals held at VDDQ ICC Core Core and analog voltage operating current – 200 mA Total current through AVDD, VDD ICC USB USB voltage supply operating current – 60 mA – mA Core current: 1.5 mA I/O current: 20 µA USB current: 2 mA For typical PVT (typical silicon, all power supplies at their respective nominal levels at 25 °C) mA Core current: 250 µA I/O current: 20 µA USB current: 1.2 mA For typical PVT (Typical silicon, all power supplies at their respective nominal levels at 25 °C) µA Core current: 60 µA I/O current: 20 µA USB current: 40 µA For typical PVT (typical silicon, all power supplies at their respective nominal levels at 25 °C) µA Core current: 0 µA I/O current: 20 µA USB current: 40 µA For typical PVT (typical silicon, all power supplies at their respective nominal levels at 25 °C) ISB1 ISB2 ISB3 Total suspend current during suspend mode with USB 3.0 PHY enabled (L1) Total suspend current during suspend mode with USB 3.0 PHY disabled (L2) Total standby current during standby mode (L3) – – – – – – ISB4 Total standby current during core power-down mode (L4) – – VRAMP Voltage ramp rate on core and I/O supplies 0.2 50 VN Noise level permitted on VDD and I/O supplies – 100 mV Max p-p noise level permitted on all supplies except AVDD VN_AVDD Noise level permitted on AVDD supply – 20 mV Max p-p noise level permitted on AVDD Document Number: 001-52136 Rev. *S V/ms Voltage ramp must be monotonic Page 20 of 53 CYUSB301X/CYUSB201X AC Timing Parameters GPIF II Timing Figure 9. GPIF II Timing in Synchronous Mode tC LK H tC LKL C LK tC LK tC O tLZ - [31:0] DQ tD S tD O H tLZ tD O H D ata 2 ( O U T) D ata 1 ( O U T) D ata ( IN) tS tH Z tC O E tD H tH C TL(IN) tC TLO tC O H C TL ( O U T) Table 9. GPIF II Timing Parameters in Synchronous Mode [2] Parameter Description Min Max Units Frequency Interface clock frequency – 100 MHz tCLK Interface clock period 10 – ns tCLKH Clock high time 4 – ns tCLKL Clock low time 4 – ns tS CTL input to clock setup time 2 – ns tH CTL input to clock hold time 0.5 – ns tDS Data in to clock setup time 2 – ns tDH Data in to clock hold time 0.5 – ns tCO Clock to data out propagation delay when DQ bus is already in output direction – 8 ns tCOE Clock to data out propagation delay when DQ lines change to output from tristate and valid data is available on the DQ bus – 9 ns tCTLO Clock to CTL out propagation delay – 8 ns tDOH Clock to data out hold 2 – ns tCOH Clock to CTL out hold 0 – ns tHZ Clock to high-Z – 8 ns tLZ Clock to low-Z 0 – ns Note 2. All parameters guaranteed by design and validated through characterization. Document Number: 001-52136 Rev. *S Page 21 of 53 CYUSB301X/CYUSB201X Figure 10. GPIF II Timing in Asynchronous Mode tDS/ tAS tDH/tAH DATA IN DATA/ ADDR tCHZ CTL# (I/P , ALE/ DLE) tCTLassert_DQlatch tCTLdeassert_DQlatch tAA/tDO tCHZ/tOEHZ tCLZ/ tOELZ DATA OUT DATA OUT CTL# (I/P, non ALE/ DLE tCTLdeassert tCTLassert tCTLalpha ALPHA O/P tCTLbeta BETA O/P 1 tCTLassert tCTLdeassert 1 tCTL# (O/P) 1. n is an integer >= 0 tDST tDHT DATA/ ADDR tCTLdeassert_DQassert tCTLassert_DQassert CTL# I/P (non DLE/ALE) Figure 11. GPIF II Timing in Asynchronous DDR Mode tDS tCTLdeassert_DqlatchDDR tCTLassert_DQlatchDDR CTL# (I/P) tDS tDH tDH DATA IN Document Number: 001-52136 Rev. *S Page 22 of 53 CYUSB301X/CYUSB201X Table 10. GPIF II Timing in Asynchronous Mode[3, 4] Note The following parameters assume one state transition Parameter Description Min Max Units tDS Data In to DLE setup time. Valid in DDR async mode. 2.3 – ns tDH Data In to DLE hold time. Valid in DDR async mode. 2 – ns tAS Address In to ALE setup time 2.3 – ns tAH Address In to ALE hold time 2 – ns tCTLassert CTL I/O asserted width for CTRL inputs without DQ input association and for outputs. 7 – ns tCTLdeassert CTL I/O deasserted width for CTRL inputs without DQ input association and for outputs. 7 – ns tCTLassert_DQassert CTL asserted pulse width for CTL inputs that signify DQ inputs valid at the asserting edge but do not employ in-built latches (ALE/DLE) for those DQ inputs. 20 – ns tCTLdeassert_DQassert CTL deasserted pulse width for CTL inputs that signify DQ input valid at the asserting edge but do not employ in-built latches (ALE/DLE) for those DQ inputs. 7 – ns tCTLassert_DQdeassert CTL asserted pulse width for CTL inputs that signify DQ inputs valid at the deasserting edge but do not employ in-built latches (ALE/DLE) for those DQ inputs. 7 – ns tCTLdeassert_DQdeassert CTL deasserted pulse width for CTL inputs that signify DQ inputs valid at the deasserting edge but do not employ in-built latches (ALE/DLE) for those DQ inputs. 20 – ns tCTLassert_DQlatch CTL asserted pulse width for CTL inputs that employ in-built latches (ALE/DLE) to latch the DQ inputs. In this non-DDR case, in-built latches are always close at the deasserting edge. 7 – ns tCTLdeassert_DQlatch CTL deasserted pulse width for CTL inputs that employ in-built latches (ALE/DLE) to latch the DQ inputs. In this non-DDR case, in-built latches always close at the deasserting edge. 10 – ns tCTLassert_DQlatchDDR CTL asserted pulse width for CTL inputs that employ in-built latches (DLE) to latch the DQ inputs in DDR mode. 10 – ns tCTLdeassert_DQlatchDDR CTL deasserted pulse width for CTL inputs that employ in-built latches (DLE) to latch the DQ inputs in DDR mode. 10 – ns tAA DQ/CTL input to DQ output time when DQ change or CTL change needs to be detected and affects internal updates of input and output DQ lines. – 30 ns tDO CTL to data out when the CTL change merely enables the output flop update whose data was already established. – 25 ns tOELZ CTL designated as OE to low-Z. Time when external devices should stop driving data. 0 – ns tOEHZ CTL designated as OE to high-Z 8 8 ns tCLZ CTL (non-OE) to low-Z. Time when external devices should stop driving data. 0 – ns tCHZ CTL (non-OE) to high-Z 30 30 ns tCTLalpha CTL to alpha change at output – 25 ns tCTLbeta CTL to beta change at output – 30 ns tDST Addr/data setup when DLE/ALE not used 2 – ns tDHT Addr/data hold when DLE/ALE not used 20 – ns Notes 3. All parameters guaranteed by design and validated through characterization. 4. "alpha" output corresponds to "early output" and "beta" corresponds to "delayed output". Please refer to the GPIFII Designer Tool for the use of these outputs. Document Number: 001-52136 Rev. *S Page 23 of 53 CYUSB301X/CYUSB201X Slave FIFO Interface FLAG Usage: The FLAG signals are monitored for flow control by the external processor. FLAG signals are outputs from FX3 that may be configured to show empty, full, or partial status for a dedicated thread or the current thread that is addressed. Synchronous Slave FIFO Read Sequence Description ■ FIFO address is stable and SLCS is asserted ■ FLAG indicates FIFO not empty status ■ SLOE is asserted. SLOE is an output-enable only, whose sole function is to drive the data bus. ■ SLRD is asserted Socket Switching Delay (Tssd): The FIFO pointer is updated on the rising edge of the PCLK, while the SLRD is asserted. This starts the propagation of data from the newly addressed location to the data bus. After a propagation delay of tco (measured from the rising edge of PCLK), the new data value is present. N is the first data value read from the FIFO. To have data on the FIFO data bus, SLOE must also be asserted. The same sequence of events is applicable for a burst read. The socket-switching delay is measured from the time EPSWITCH# is asserted by the master, with the new socket address on the address bus, to the time the Current_Thread_DMA_Ready flag is asserted. For the Producer socket, the flag is asserted when it is ready to receive data in the DMA buffer. For the Consumer socket, the flag is asserted when it is ready to drive data out of the DMA buffer. For a synchronous slave FIFO interface, the switching delay is measured in the number of GPIF interface clock cycles; for an asynchronous slave FIFO interface, in PIB clock cycles. This is applicable only for the 5-bit Slave FIFO interface; there is no socket-switching delay in FX3's 2-bit Slave FIFO interface, which makes use of thread switching in the GPIF™ II state machine. Note For burst mode, the SLRD# and SLOE# are asserted during the entire duration of the read. When SLOE# is asserted, the data bus is driven (with data from the previously addressed FIFO). For each subsequent rising edge of PCLK, while the SLRD# is asserted, the FIFO pointer is incremented and the next data value is placed on the data bus. Figure 12. Synchronous Slave FIFO Read Mode Synchronous Read Cycle Timing t CYC PCLK tCH tCL t ACCD SLCS tAS tAH FIFO ADDR An Am t RDS tRDH SLRD SLOE Tssd t ACCD t CFLG FLAGA ( dedicated thread Flag for An ) ( 1 = Not Empty 0 = Empty ) Tssd t CFLG FLAGB (dedicated thread Flag for Am ) ( 1 = Not Empty 0 = Empty ) tOELZ Data Out High-Z tCDH tOEZ Data driven:DN (An) High-Z DN (An) tCO DN ( Am) t OEZ DN+1 (Am) DN+2 (Am) High-Z SLWR( HIGH) Document Number: 001-52136 Rev. *S Page 24 of 53 CYUSB301X/CYUSB201X Short Packet: A short packet can be committed to the USB host by using the PKTEND#. The external device or processor should be designed to assert the PKTEND# along with the last word of data and SLWR# pulse corresponding to the last word. The FIFOADDR lines must be held constant during the PKTEND# assertion. Synchronous Slave FIFO Write Sequence Description ■ FIFO address is stable and the signal SLCS# is asserted ■ External master or peripheral outputs the data to the data bus ■ SLWR# is asserted ■ While the SLWR# is asserted, data is written to the FIFO and on the rising edge of the PCLK, the FIFO pointer is incremented ■ The FIFO flag is updated after a delay of t WFLG from the rising edge of the clock Zero-Length Packet: The external device or processor can signal a Zero-Length Packet (ZLP) to FX3 simply by asserting PKTEND#, without asserting SLWR#. SLCS# and address must be driven as shown in Figure 13. The same sequence of events is also applicable for burst write Note For the burst mode, SLWR# and SLCS# are asserted for the entire duration, during which all the required data values are written. In this burst write mode, after the SLWR# is asserted, the data on the FIFO data bus is written to the FIFO on every rising edge of PCLK. The FIFO pointer is updated on each rising edge of PCLK. Figure 13. Synchronous Slave FIFO Write Mode Synchronous Write Cycle Timing tCYC PCLK tCH tCL SLCS tAS tAH Am An FIFO ADDR tWRS Tssd tWRH SLWR t CFLG tFAD FLAGA dedicated thread FLAG for An ( 1 = Not Full0 = Full) Tssd FLAGB current thread FLAG for Am ( 1 = Not Full0 = Full) Data IN tDS tDH High-Z DN (An) tFAD tDS tDH DN ( Am) t CFLG tDH DN+1 (Am) DN+2 (Am) tPES tPEH PKTEND SLOE ( HIGH) Document Number: 001-52136 Rev. *S Page 25 of 53 CYUSB301X/CYUSB201X Figure 14. Synchronous Slave FIFO ZLP Write Cycle Timing Synchronous ZLP Write Cycle Timing tCYC PCLK t CH tCL SLCS tAS t AH An FIFO ADDR SLWR (HIGH) tPES tPEH PKTEND t CFLG FLAGA dedicated thread FLAG for An (1 = Not Full 0= Full) FLAGB current thread FLAG for Am (1 = Not Full 0= Full) Data IN High-Z SLOE (HIGH) Table 11. Synchronous Slave FIFO Parameters[5] Parameter Description FREQ Interface clock frequency tCYC Clock period tCH Clock high time tCL Clock low time tRDS SLRD# to CLK setup time tRDH SLRD# to CLK hold time tWRS SLWR# to CLK setup time tWRH SLWR# to CLK hold time tCO Clock to valid data tDS Data input setup time tDH CLK to data input hold tAS Address to CLK setup time tAH CLK to address hold time tOELZ SLOE# to data low-Z tCFLG CLK to flag output propagation delay tOEZ SLOE# deassert to Data Hi Z tPES PKTEND# to CLK setup tPEH CLK to PKTEND# hold tCDH CLK to data output hold tSSD Socket switching delay tACCD Latency from SLRD# to Data tFAD Latency from SLWR# to FLAG Note Three-cycle latency from ADDR to DATA/FLAGS. Min – 10 4 4 2 0.5 2 0.5 – 2 0.5 2 0.5 0 – – 2 0.5 2 2 2 3 Max 100 – – – – – – – 8 – – – – – 8 8 – – – 68 2 3 Units MHz ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns Clock cycles Clock cycles Clock cycles Note 5. All parameters guaranteed by design and validated through characterization. Document Number: 001-52136 Rev. *S Page 26 of 53 CYUSB301X/CYUSB201X Asynchronous Slave FIFO Read Sequence Description ■ FIFO address is stable and the SLCS# signal is asserted. ■ SLOE# is asserted. This results in driving the data bus. In Figure 15, data N is the first valid data read from the FIFO. For data to appear on the data bus during the read cycle, SLOE# must be in an asserted state. SLRD# and SLOE# can also be tied. ■ SLRD # is asserted. The same sequence of events is also shown for a burst read. ■ Data from the FIFO is driven after assertion of SLRD#. This data is valid after a propagation delay of tRDO from the falling edge of SLRD#. ■ FIFO pointer is incremented on deassertion of SLRD# Note In the burst read mode, during SLOE# assertion, the data bus is in a driven state (data is driven from a previously addressed FIFO). After assertion of SLRD# data from the FIFO is driven on the data bus (SLOE# must also be asserted). The FIFO pointer is incremented after deassertion of SLRD#. Figure 15. Asynchronous Slave FIFO Read Mode Asynchronous Read Cycle Timing SLCS tAS tAH An FIFO ADDR tRDl Am tRDh SLRD SLOE tFLG tRFLG FLAGA dedicated thread Flag for An (1=Not empty 0 = Empty) FLAGB dedicated thread Flag for Am (1=Not empty 0 = Empty) tOE tRDO tOH tOE tRDO tRDO tOH tLZ Data Out High-Z DN(An) DN(An) DN(Am) DN+1(Am) DN+2(Am) SLWR (HIGH) Document Number: 001-52136 Rev. *S Page 27 of 53 CYUSB301X/CYUSB201X Asynchronous Slave FIFO Write Sequence Description ■ FIFO address is driven and SLCS# is asserted ■ SLWR# is asserted. SLCS# must be asserted with SLWR# or before SLWR# is asserted ■ Data must be present on the tWRS bus before the deasserting edge of SLWR# ■ Deassertion of SLWR# causes the data to be written from the data bus to the FIFO, and then the FIFO pointer is incremented ■ The FIFO flag is updated after the tWFLG from the deasserting edge of SLWR. The same sequence of events is shown for a burst write. Short Packet: A short packet can be committed to the USB host by using the PKTEND#. The external device or processor should be designed to assert the PKTEND# along with the last word of data and SLWR# pulse corresponding to the last word. The FIFOADDR lines must be held constant during the PKTEND# assertion. Zero-Length Packet: The external device or processor can signal a zero-length packet (ZLP) to FX3 simply by asserting PKTEND#, without asserting SLWR#. SLCS# and the address must be driven as shown in Figure 17 on page 29. FLAG Usage: The FLAG signals are monitored by the external processor for flow control. FLAG signals are FX3 outputs that can be configured to show empty, full, and partial status for a dedicated address or the current address. Note that in the burst write mode, after SLWR# deassertion, the data is written to the FIFO, and then the FIFO pointer is incremented. Figure 16. Asynchronous Slave FIFO Write Mode Asynchronous Write Cycle Timing SLCS tAS tAH An FIFO ADDR tWRl Am tWRh SLWR tFLG t WFLG FLAGA dedicated thread Flag for An (1= Not Full 0 = Full) t WFLG FLAGB dedicated thread Flag for Am (1= Not Full 0 = Full) DATA In tWR S High-Z tWRH tWR t WRH S DN (An) DN (Am) DN+1 (Am) DN+2 (Am) t WRPE t PEh PKTEND SLOE ( HIGH) tWRPE: SLWR# de- assert to PKTEND deassert = 2 ns min( This means that PKTEND should not be be deasserted before SLWR #) Note: PKTEND must be asserted at the same time as SLWR #. Document Number: 001-52136 Rev. *S Page 28 of 53 CYUSB301X/CYUSB201X Figure 17. Asynchronous ZLP Write Cycle Timing SLCS tA S tA H An F IF O A D D R SLW R ( H IG H) tP E l t P E h PKTEND t W FLG FLAG A d e d ic a te d th re a d F la g fo r A n ( 1 = N o t F u ll 0 = F u ll) FLAG B d e d ic a te d th re a d F la g fo r A m ( 1 = N o t F u ll 0 = F u ll) H ig h- Z D A T A In SLO E ( H IG H) Table 12. Asynchronous Slave FIFO Parameters[6] Parameter Min Max Units SLRD# low 20 – ns tRDh SLRD# high 10 – ns tAS Address to SLRD#/SLWR# setup time 7 – ns tAH SLRD#/SLWR#/PKTEND to address hold time 2 – ns tRFLG SLRD# to FLAGS output propagation delay – 35 ns tFLG ADDR to FLAGS output propagation delay – 22.5 ns tRDO SLRD# to data valid – 25 ns tOE OE# low to data valid – 25 ns tLZ OE# low to data low-Z 0 – ns tOH SLOE# deassert data output hold – 22.5 ns tWRI SLWR# low 20 – ns tWRh SLWR# high 10 – ns tWRS Data to SLWR# setup time 7 – ns tRDI Description tWRH SLWR# to Data Hold time 2 – ns tWFLG SLWR#/PKTEND to Flags output propagation delay – 35 ns tPEI PKTEND low 20 – ns tPEh PKTEND high 7.5 – ns tWRPE SLWR# deassert to PKTEND deassert 2 – ns Note 6. All parameters guaranteed by design and validated through characterization. Document Number: 001-52136 Rev. *S Page 29 of 53 CYUSB301X/CYUSB201X Host Processor Interface (P-Port) Timing Asynchronous SRAM Timing Figure 18. Non-multiplexed Asynchronous SRAM Read Timing Socket Read – Address Transition Controlled Timing (OE# is asserted) A[0] tAA tAH tOH DATA OUT HIGH IMPEDANCE DATA VALID DATA VALID DATA VALID tOE OE# OE# Controlled Timing ADDRESS WE# (HIGH) tAOS CE# tOHC tRC OE# tOHH tOE tOEZ tOLZ DATA OUT HIGH IMPEDANCE Document Number: 001-52136 Rev. *S DATA VALID HIGH IMPEDANCE DATA VALID HIGH IMPEDANCE Page 30 of 53 CYUSB301X/CYUSB201X Figure 19. Non-multiplexed Asynchronous SRAM Write Timing (WE# and CE# Controlled) Write Cycle 1 WE# Controlled, OE# High During Write tWC ADDRESS tCW CE# tAW tAH tWP WE# tAS tWPH OE# tDS DATA I/O tDH VALID DATA VALID DATA tWHZ Write Cycle 2 CE# Controlled, OE# High During Write tWC ADDRESS tAS tCW tCPH CE# tAW tAH tWP WE# OE# tDS DATA I/O VALID DATA tDH VALID DATA tWHZ Document Number: 001-52136 Rev. *S Page 31 of 53 CYUSB301X/CYUSB201X Figure 20. Non-multiplexed Asynchronous SRAM Write Timing (WE# controlled, OE# LOW) Write Cycle 3 WE# Controlled. OE# Low tWC tCW CE# tAW tAH tAS tWP WE# tDS DATA I/O tDH VALID DATA tOW tWHZ Note: tWP must be adjusted such that tWP > tWHZ + tDS Table 13. Asynchronous SRAM Timing Parameters[7] Parameter – Description SRAM interface bandwidth Min Max Units – 61.5 Mbps 32.5 – ns tRC Read cycle time tAA Address to data valid – 30 ns tAOS Address to OE# LOW setup time 7 – ns tOH Data output hold from address change 3 – ns ns tOHH OE# HIGH hold time 7.5 – tOHC OE# HIGH to CE# HIGH 2 – ns tOE OE# LOW to data valid – 25 ns tOLZ OE# LOW to LOW-Z 0 – ns tWC Write cycle time 30 – ns tCW CE# LOW to write end 30 – ns tAW Address valid to write end 30 – ns tAS Address setup to write start 7 – ns tAH Address hold time from CE# or WE# 2 – ns tWP WE# pulse width 20 – ns tWPH WE# HIGH time 10 – ns tCPH CE# HIGH time 10 – ns tDS Data setup to write end 7 – ns tDH Data hold to write end 2 – ns tWHZ Write to DQ HIGH-Z output – 22.5 ns tOEZ OE# HIGH to DQ HIGH-Z output – 22.5 ns tOW End of write to LOW-Z output 0 – ns Note 7. All parameters guaranteed by design and validated through characterization. Document Number: 001-52136 Rev. *S Page 32 of 53 CYUSB301X/CYUSB201X ADMux Timing for Asynchronous Access Figure 21. ADMux Asynchronous Random Read tRC tACC Valid Address A[0:7]/DQ[0:15] tAVS tAVH tVP ADV# WE# (HIGH) Valid Addr Valid Data tCEAV tHZ tCO CE# tCPH tHZ tOLZ tOE OE# tAVOE Note: 1. Multiple read cycles can be executed while keeping CE# low. 2. Read operation ends with either de-assertion of either OE# or CE#, whichever comes earlier. Figure 22. ADMux Asynchronous Random Write tWC Address Valid A[0:7]/DQ[0:15] Valid Addr Data Valid tAW tAVS ADV# tCEAV CE# tAVH tDS tDH tVPH tVP tCPH tCW tWP WE# tWPH tAVWE Note: 1. Multiple write cycles can be executed while keeping CE# low. 2. Write operation ends with de-assertion of either WE# or CE#, whichever comes earlier. Document Number: 001-52136 Rev. *S Page 33 of 53 CYUSB301X/CYUSB201X Table 14. Asynchronous ADMux Timing Parameters[8] Parameter Description Min Max Units Notes ADMux Asynchronous READ Access Timing Parameters tRC Read cycle time (address valid to address valid) tACC Address valid to data valid – 32 ns – tCO CE# assert to data valid – 34.5 ns – tAVOE ADV# deassert to OE# assert 2 – ns – tOLZ OE# assert to data LOW-Z 0 – ns – 54.5 – ns This parameter is dependent on when the P-port processors deasserts OE# tOE OE# assert to data valid – 25 ns – tHZ Read cycle end to data HIGH-Z – 22.5 ns – tWC Write cycle time (Address Valid to Address Valid) – 52.5 ns – tAW Address valid to write end 30 – ns – tCW CE# assert to write end 30 – ns – tAVWE ADV# deassert to WE# assert 2 – ns – tWP WE# LOW pulse width 20 – ns – tWPH WE# HIGH pulse width 10 – ns – tDS Data valid setup to WE# deassert 18 – ns – tDH Data valid hold from WE# deassert 2 – ns – tAVS Address valid setup to ADV# deassert tAVH Address valid hold from ADV# deassert tVP ADV# LOW pulse width tCPH CE# HIGH pulse width tVPH ADV# HIGH pulse width tCEAV CE# assert to ADV# assert ADMux Asynchronous WRITE Access Timing Parameters ADMux Asynchronous Common READ/WRITE Access Timing Parameters 5 – ns – 2 – ns – 7.5 – ns – 10 – ns – 15 – ns – 0 – ns – Note 8. All parameters guaranteed by design and validated through characterization. Document Number: 001-52136 Rev. *S Page 34 of 53 CYUSB301X/CYUSB201X Synchronous ADMux Timing Figure 23. Synchronous ADMux Interface – Read Cycle Timing tCLK 2- cycle latency from OE# to DATA tCLKH tCLKL CLK tCO tS A[0:7]/DQ[0:31] tH Valid Data Valid Address tS tH ADV# tOHZ tS CE# tAVOE tOLZ OE# tKW tKW RDY tCH WE# (HIGH) Note: 1) External P-Port processor and FX3 operate on the same clock edge 2) External processor sees RDY assert 2 cycles after OE # asserts andand sees RDY deassert a cycle after the data appears on the output 3) Valid output data appears 2 cycle after OE # asserted. The data is held until OE # deasserts 4) Two cycle latency is shown for 0-100 MHz operation. Latency can be reduced by 1 cycle for operations at less than 50 MHz (this 1 cycle latency is not supported by the bootloader) Figure 24. Synchronous ADMux Interface – Write Cycle Timing 2-cycle latency between WE# and data being latched 2-cycle latency between this clk edge and RDY deassertion seen by the host CLK tCLK tS A[0:7]/DQ[0:31] tDS tH Valid Address tS tDH Valid Data tH ADV# tS CE# tAVWE tS tH WE# tKW RDY tKW Note: 1) External P-Port processor and FX3 operate on the same clock edge 2) External processor sees RDY assert 2 cycles after WE # asserts and deassert 3 cycles after the edge sampling the data. 3) Two cycle latency is shown for 0-100 MHz operation. Latency can be reduced by 1 cycle for operations at less than 50 MHz (this 1 cycle latency is not supported by the bootloader ) Document Number: 001-52136 Rev. *S Page 35 of 53 CYUSB301X/CYUSB201X Figure 25. Synchronous ADMux Interface – Burst Read Timing 2-cycle latency from OE# to Data tCLK tCLKH tCLKL CLK tCO tS A[0:7]/DQ[0:31] tCH tH Valid Address tS D0 D1 D2 D3 tH ADV# tHZ tS CE# tAVOE tOLZ OE# tKW tKW RDY Note: 1) External P-Port processor and FX3 work operate on the same clock edge 2) External processor sees RDY assert 2 cycles after OE # asserts andand sees RDY deassert a cycle after the last burst data appears on the output 3) Valid output data appears 2 cycle after OE # asserted. The last burst data is held until OE # deasserts 4) Burst size of 4 is shown. Transfer size for the operation must be a multiple of burst size. Burst size is usually power of 2. RDY will not deassert in the middle of the burst. 5) External processor cannot deassert OE in the middle of a burst. If it does so, any bytes remaining in the burst packet could get lost. 6) Two cycle latency is shown for 0-100 MHz operation. Latency can be reduced by 1 cycle for operations at less than 50 MHz (this 1 cycle latency is not supported by the bootloader) Figure 26. Sync ADMux Interface – Burst Write Timing 2-cycle latency between WE# and data being latched tCLKH 2-cycle latency between this clk edge and RDY deassertion seen by the host tCLKL CLK tCLK tS A[0:7]/DQ[0:31] tDS tH D0 Valid Address tS tDH tDH D1 D2 D3 tH ADV# tS CE# tAVWE WE# RDY tKW tKW Note: 1) External P-Port processor and FX3 operate on the same clock edge 2) External processor sees RDY assert 2 cycles after WE # asserts and deasserts 3 cycles after the edge sampling the last burst data. 3) Transfer size for the operation must be a multiple of burst size. Burst size is usually power of 2. RDY will not deassert in the middle of the burst. Burst size of 4 is shown 4) External processor cannot deassert WE in the middle of a burst. If it does so, any bytes remaining in the burst packet could get lost. 5)Two cycle latency is shown for 0-100 MHz operation. Latency can be reduced by 1 cycle for operations at less than 50 MHz (this 1 cycle latency is not supported by the bootloader) Document Number: 001-52136 Rev. *S Page 36 of 53 CYUSB301X/CYUSB201X Table 15. Synchronous ADMux Timing Parameters[9] Parameter Description Min Max Unit FREQ Interface clock frequency – 100 MHz tCLK Clock period 10 – ns tCLKH Clock HIGH time 4 – ns tCLKL Clock LOW time 4 – ns tS CE#/WE#/DQ setup time 2 – ns tH CE#/WE#/DQ hold time 0.5 – ns tCH Clock to data output hold time 0 – ns tDS Data input setup time 2 – ns tDH Clock to data input hold 0.5 – ns tAVDOE ADV# HIGH to OE# LOW 0 – ns tAVDWE ADV# HIGH to WE# LOW 0 – ns tHZ CE# HIGH to Data HIGH-Z – 8 ns tOHZ OE# HIGH to Data HIGH-Z – 8 ns tOLZ OE# LOW to Data LOW-Z 0 – ns tKW Clock to RDY valid – 8 ns Serial Peripherals Timing I2C Timing Figure 27. I2C Timing Definition Note 9. All parameters guaranteed by design and validated through characterization. Document Number: 001-52136 Rev. *S Page 37 of 53 CYUSB301X/CYUSB201X Table 16. I2C Timing Parameters[10] Parameter Description Min Max Units I2C Standard Mode Parameters fSCL SCL clock frequency 0 100 kHz tHD:STA Hold time START condition 4 – µs tLOW LOW period of the SCL 4.7 – µs tHIGH HIGH period of the SCL 4 – µs tSU:STA Setup time for a repeated START condition 4.7 – µs tHD:DAT Data hold time 0 – µs tSU:DAT Data setup time 250 – ns tr Rise time of both SDA and SCL signals – 1000 ns tf Fall time of both SDA and SCL signals – 300 ns tSU:STO Setup time for STOP condition 4 – µs tBUF Bus free time between a STOP and START condition 4.7 – µs tVD:DAT Data valid time – 3.45 µs tVD:ACK Data valid ACK – 3.45 µs tSP Pulse width of spikes that must be suppressed by input filter n/a n/a 0 400 kHz I 2C Fast Mode Parameters fSCL SCL clock frequency tHD:STA Hold time START condition 0.6 – µs tLOW LOW period of the SCL 1.3 – µs tHIGH HIGH period of the SCL 0.6 – µs tSU:STA Setup time for a repeated START condition 0.6 – µs tHD:DAT Data hold time 0 – µs tSU:DAT Data setup time 100 – ns tr Rise time of both SDA and SCL signals – 300 ns tf Fall time of both SDA and SCL signals – 300 ns tSU:STO Setup time for STOP condition 0.6 – µs tBUF Bus free time between a STOP and START condition 1.3 – µs tVD:DAT Data valid time – 0.9 µs tVD:ACK Data valid ACK – 0.9 µs tSP Pulse width of spikes that must be suppressed by input filter 0 50 ns Note 10. All parameters guaranteed by design and validated through characterization. Document Number: 001-52136 Rev. *S Page 38 of 53 CYUSB301X/CYUSB201X Table 16. I2C Timing Parameters[10] (continued) Parameter Description Min Max Units 2 I C Fast Mode Plus Parameters (Not supported at I2C_VDDQ=1.2 V) fSCL SCL clock frequency 0 1000 kHz tHD:STA Hold time START condition 0.26 – µs tLOW LOW period of the SCL 0.5 – µs tHIGH HIGH period of the SCL 0.26 – µs tSU:STA Setup time for a repeated START condition 0.26 – µs tHD:DAT Data hold time 0 – µs tSU:DAT Data setup time 50 – ns tr Rise time of both SDA and SCL signals – 120 ns tf Fall time of both SDA and SCL signals – 120 ns tSU:STO Setup time for STOP condition 0.26 – µs tBUF Bus-free time between a STOP and START condition 0.5 – µs tVD:DAT Data valid time – 0.45 µs tVD:ACK Data valid ACK – 0.55 µs tSP Pulse width of spikes that must be suppressed by input filter 0 50 ns I2S Timing Diagram Figure 28. I2S Transmit Cycle tT tTR tTF tTL tTH SCK tThd SA, WS (output) tTd Table 17. I2S Timing Parameters[11] Parameter Description Min Max Units Ttr – ns transmitter cycle LOW period 0.35 Ttr – ns transmitter cycle HIGH period 0.35 Ttr – ns – 0.15 Ttr ns – 0.15 Ttr ns transmitter data hold time 0 – ns transmitter delay time – 0.8tT ns tT I2S transmitter clock cycle tTL I 2S tTH I 2S tTR I 2S transmitter rise time tTF I2S transmitter fall time tThd I 2S tTd I 2S Note tT is selectable through clock gears. Max Ttr is designed for 96-kHz codec at 32 bits to be 326 ns (3.072 MHz). Note 11. All parameters guaranteed by design and validated through characterization. Document Number: 001-52136 Rev. *S Page 39 of 53 CYUSB301X/CYUSB201X SPI Timing Specification Figure 29. SPI Timing SSN (output) tssnh tsck tlead SCK (CPOL=0, Output) trf twsck SCK (CPOL=1, Output) tsdi MISO (input) tlag twsck thoi MSB LSB td tsdd tdis tdi v MOSI (output) LSB MSB SPI Master Timing for CPHA = 0 SSN (output) SCK (CPOL=0, Output) tssnh tsck tlead twsck trf tlag twsck SCK (CPOL=1, Output) tsdi MISO (input) thoi LSB tdv MOSI (output) MSB tdis tdi LSB MSB SPI Master Timing for CPHA = 1 Document Number: 001-52136 Rev. *S Page 40 of 53 CYUSB301X/CYUSB201X Table 18. SPI Timing Parameters[12] Parameter fop tsck twsck tlead tlag trf tsdd tdv tdi tssnh tsdi thoi tdis Description Operating frequency Cycle time Clock high/low time SSN-SCK lead time Enable lag time Rise/fall time Output SSN to valid data delay time Output data valid time Output data invalid Minimum SSN high time Data setup time input Data hold time input Disable data output on SSN high Min 0 30 13.5 1/2 tsck[13 ]-5 0.5 – – – 0 10 8 0 0 Max 33 – – 1.5 tsck[13]+ 5 1.5 tsck[13]+5 8 5 5 – – – – – Units MHz ns ns ns ns ns ns ns ns ns ns ns ns Notes 12. All parameters guaranteed by design and validated through characterization. 13. Depends on LAG and LEAD setting in the SPI_CONFIG register. Document Number: 001-52136 Rev. *S Page 41 of 53 CYUSB301X/CYUSB201X Reset Sequence FX3’s hard reset sequence requirements are specified in this section. Table 19. Reset and Standby Timing Parameters Parameter Definition tRPW Minimum RESET# pulse width tRH Minimum high on RESET# tRR Reset recovery time (after which Boot loader begins firmware download) tSBY Time to enter standby/suspend (from the time MAIN_CLOCK_EN/ MAIN_POWER_EN bit is set) tWU Time to wakeup from standby tWH Minimum time before Standby/Suspend source may be reasserted Conditions Min (ms) Max (ms) Clock Input 1 – Crystal Input 1 – – 5 – – Clock Input 1 Crystal Input 5 – – 1 Clock Input 1 – Crystal Input 5 – – 5 – Figure 30. Reset Sequence VDD ( core ) xVDDQ XTALIN/ CLKIN XTALIN/ CLKIN must be stable before exiting Standby/Suspend Mandatory Reset Pulse tRh tRR Hard Reset RESET # tWH tRPW Standby/ Suspend Source tSBY Standby/Suspend source Is asserted (MAIN_POWER_EN/ MAIN_CLK_EN bit is set) Document Number: 001-52136 Rev. *S tWU Standby/Suspend source Is deasserted Page 42 of 53 CYUSB301X/CYUSB201X Package Diagram Figure 31. 121-ball BGA Package Diagram 2X 0.10 C E1 E B A 11 10 9 8 7 6 5 (datum B) 4 3 2 A1 CORNER 1 7 A1 CORNER A B C D 6 E SD D1 F D (datum A) G H J K eD 0.10 C 2X L 6 eE SE TOP VIEW BOTTOM VIEW 0.20 C DETAIL A A1 0.08 C C 121XØb 5 A Ø0.15 M C A B Ø0.08 M C SIDE VIEW DETAIL A NOTES: 1. ALL DIMENSIONS ARE IN MILLIMETERS. DIMENSIONS SYMBOL MIN. NOM. MAX. A - - 1.20 A1 0.15 - - D 10.00 BSC E 10.00 BSC D1 8.00 BSC E1 8.00 BSC MD 11 ME 11 N 121 b 0.25 0.30 eD 0.80 BSC eE 0.80 BSC SD 0.00 SE 0.00 2. SOLDER BALL POSITION DESIGNATION PER JEP95, SECTION 3, SPP-020. 3. "e" REPRESENTS THE SOLDER BALL GRID PITCH. 4. SYMBOL "MD" IS THE BALL MATRIX SIZE IN THE "D" DIRECTION. SYMBOL "ME" IS THE BALL MATRIX SIZE IN THE "E" DIRECTION. N IS THE NUMBER OF POPULATED SOLDER BALL POSITIONS FOR MATRIX SIZE MD X ME. 5. DIMENSION "b" IS MEASURED AT THE MAXIMUM BALL DIAMETER IN A PLANE PARALLEL TO DATUM C. 6. "SD" AND "SE" ARE MEASURED WITH RESPECT TO DATUMS A AND B AND DEFINE THE POSITION OF THE CENTER SOLDER BALL IN THE OUTER ROW. 0.35 WHEN THERE IS AN ODD NUMBER OF SOLDER BALLS IN THE OUTER ROW, "SD" OR "SE" = 0. WHEN THERE IS AN EVEN NUMBER OF SOLDER BALLS IN THE OUTER ROW, "SD" = eD/2 AND "SE" = eE/2. 7. A1 CORNER TO BE IDENTIFIED BY CHAMFER, LASER OR INK MARK METALIZED MARK, INDENTATION OR OTHER MEANS. 8. "+" INDICATES THE THEORETICAL CENTER OF DEPOPULATED SOLDER BALLS. 001-54471 *E Document Number: 001-52136 Rev. *S Page 43 of 53 CYUSB301X/CYUSB201X Figure 32. 131-ball WLCSP (5.099 × 4.695 × 0.60 mm) Package Diagram 001-62221 *C Note Underfill is required on the board design. Contact [email protected] for details. Document Number: 001-52136 Rev. *S Page 44 of 53 CYUSB301X/CYUSB201X Ordering Information Table 20. Ordering Information Ordering Code USB SRAM (kB) GPIF II Data Bus Width Operating Temperature Package Type CYUSB3011-BZXC USB 3.0 256 16-bit 0 °C to +70 °C 121-ball BGA CYUSB3012-BZXC USB 3.0 256 32-bit 0 °C to +70 °C 121-ball BGA CYUSB3013-BZXC USB 3.0 512 16-bit 0 °C to +70 °C 121-ball BGA CYUSB3014-BZXC USB 3.0 512 32-bit 0 °C to +70 °C 121-ball BGA CYUSB3014-BZXI USB 3.0 512 32-bit –40°C to +85°C 121-ball BGA CYUSB3014-FBXCT USB 3.0 512 32-bit 0 °C to +70 °C 131-ball WLCSP CYUSB3014-FBXIT USB 3.0 512 32-bit –40 °C to +85 °C 131-ball WLCSP CYUSB2014-BZXC USB 2.0 512 32-bit 0 °C to +70 °C 121-ball BGA CYUSB2014-BZXI USB 2.0 512 32-bit –40 °C to +85 °C 121-ball BGA Ordering Code Definitions Document Number: 001-52136 Rev. *S Page 45 of 53 CYUSB301X/CYUSB201X Acronyms Document Conventions Acronym Description Units of Measure DMA direct memory access FIFO first in, first out °C degree Celsius GPIF general programmable interface µA microamperes HNP host negotiation protocol µs microseconds I2C inter-integrated circuit mA milliamperes I2S inter IC sound Mbps Megabits per second MISO master in, slave out MBps Megabytes per second MOSI master out, slave in MHz mega hertz MMC multimedia card ms milliseconds MSC mass storage class ns nanoseconds MTP media transfer protocol ohms OTG on-the-go pF pico Farad OVP overvoltage protection V volts PHY physical layer PLL phase locked loop PMIC power management IC PVT process voltage temperature RTOS real-time operating system SCL serial clock line SCLK serial clock SD secure digital SD secure digital SDA serial data clock SDIO secure digital input / output SLC single-level cell SLCS Slave Chip Select SLOE Slave Output Enable SLRD Slave Read SLWR Slave Write SPI serial peripheral interface SRP session request protocol SSN SPI slave select (Active low) UART universal asynchronous receiver transmitter UVC USB Video Class USB universal serial bus WLCSP wafer level chip scale package Document Number: 001-52136 Rev. *S Symbol Unit of Measure Page 46 of 53 CYUSB301X/CYUSB201X Errata This section describes the errata for Revision C of the FX3. Details include errata trigger conditions, scope of impact, available workaround, and silicon revision applicability. Contact your local Cypress Sales Representative if you have questions. Part Numbers Affected Part Number Device Characteristics CYUSB301x-xxxx All Variants CYUSB201x-xxxx All Variants Qualification Status Product Status: Production Errata Summary The following table defines the errata applicability to available Rev. C EZ-USB FX3 SuperSpeed USB Controller family devices. Items [Part Number] Silicon Revision 1. Turning off VIO1 during Normal, Suspend, and Standby modes causes the FX3 to stop working. CYUSB301x-xxxx CYUSB201x-xxxx Rev. C, B, ES 2. USB enumeration failure in USB boot mode when FX3 is self-powered. CYUSB301x-xxxx CYUSB201x-xxxx Rev. C, B, ES 3. Extra ZLP is generated by the COMMIT action in the GPIF II state. CYUSB301x-xxxx CYUSB201x-xxxx Rev. C, B, ES 4. Invalid PID Sequence in USB 2.0 ISOC data transfer. CYUSB301x-xxxx CYUSB201x-xxxx Rev. C, B, ES 5. USB data transfer errors are seen when ZLP is followed by data packet within same microframe. CYUSB301x-xxxx CYUSB201x-xxxx Rev. C, B, ES 6. Bus collision is seen when the I2C block is used as a master in the I2C Multi-master configuration. CYUSB301x-xxxx CYUSB201x-xxxx Rev. C, B, ES Fix Status Workaround provided Workaround provided Workaround provided Workaround provided Workaround provided Use FX3 in single-master configuration 1. Turning off VIO1 during Normal, Suspend, and Standby modes causes the FX3 to stop working. ■Problem Definition Turning off the VIO1 during Normal, Suspend, and Standby modes will cause the FX3 to stop working. ■Parameters Affected N/A ■Trigger Conditions This condition is triggered when the VIO1 is turned off during Normal, Suspend, and Standby modes. ■Scope Of Impact FX3 stops working. ■Workaround VIO1 must stay on during Normal, Suspend, and Standby modes. ■Fix Status No fix. Workaround is required. 2. USB enumeration failure in USB boot mode when FX3 is self-powered. ■Problem Definition FX3 device may not enumerate in USB boot mode when it is self-powered. The bootloader is designed for bus power mode. It does not make use of the VBUS pin on the USB connector to detect the USB connection and expect that USB bus is connected to host if it is powered. If FX3 is not already connected to the USB host when it is powered, then it enters into low-power mode and does not wake up when connected to USB host. ■Parameters Affected N/A Document Number: 001-52136 Rev. *S Page 47 of 53 CYUSB301X/CYUSB201X ■Trigger Conditions This condition is triggered when FX3 is self-powered in USB boot mode. ■Scope Of Impact Device does not enumerate ■Workaround Reset the device after connecting to USB host. ■Fix Status No fix. Workaround is required. 3. Extra ZLP is generated by the COMMIT action in the GPIF II state. ■Problem Definition When COMMIT action is used in a GPIF-II state without IN_DATA action then an extra Zero Length Packet (ZLP) is committed along with the data packets. ■Parameters Affected N/A ■Trigger Conditions This condition is triggered when COMMIT action is used in a state without IN_DATA action. ■Scope Of Impact Extra ZLP is generated. ■Workaround Use IN_DATA action along with COMMIT action in the same state. ■Fix Status No fix. Workaround is required. 4. Invalid PID Sequence in USB 2.0 ISOC data transfer. ■Problem Definition When the FX3 device is functioning as a high speed USB device with high bandwidth isochronous endpoints, the PID sequence of the ISO data packets is governed solely by the isomult setting. The length of the data packet is not considered while generating the PID sequence during each microframe. For example, even if a short packet is being sent on an endpoint with MULT set to 2; the PID used will be DATA2 ■Parameters Affected N/A ■Trigger Conditions This condition is triggered when high bandwidth ISOC transfer endpoints are used. ■Scope Of Impact ISOC data transfers failure. ■Workaround This problem can be worked around by reconfiguring the endpoint with a lower isomult setting prior to sending short packets, and then switching back to the original value. ■Fix Status No fix. Workaround is required. 5. USB data transfer errors are seen when ZLP is followed by data packet within same microframe. ■Problem Definition Some data transfer errors may be seen if a Zero Length Packet is followed very quickly (within one microframe or 125 us) by another data packet on a burst enabled USB IN endpoint operating at super speed. ■Parameters Affected N/A ■Trigger Conditions This condition is triggered in SuperSpeed transfer with ZLPs ■Scope Of Impact Data failure and lower data speed. ■Workaround The solution is to ensure that some time is allowed to elapse between a ZLP and the next data packet on burst enabled USB IN endpoints. If this cannot be ensured at the data source, the CyU3PDmaChannelSetSuspend() API can be used to suspend the Document Number: 001-52136 Rev. *S Page 48 of 53 CYUSB301X/CYUSB201X corresponding USB DMA socket on seeing the EOP condition. The channel operation can then be resumed as soon as the suspend callback is received. ■Fix Status No fix. Workaround is required. 6. Bus collision is seen when the I2C block is used as a master in the I2C Multi-master configuration. ■Problem definition When FX3 is used as a master in the I2C multi-master configuration, there can be occasional bus collisions. ■Parameters affected NA ■Trigger Conditions This condition is triggered only when the FX3 I2C block operates in Multi-master configuration. ■Scope Of Impact The FX3 I2C block can transmit data when the I2C bus is not idle leading to bus collision. ■Workaround Use FX3 as a single master. ■Fix Status No fix. Document Number: 001-52136 Rev. *S Page 49 of 53 CYUSB301X/CYUSB201X Document History Page Document Title: CYUSB301X/CYUSB201X, EZ-USB® FX3: SuperSpeed USB Controller Document Number: 001-52136 Orig. of Submission Revision ECN Description of Change Change Date ** 2669761 VSO / 03/06/2009 New data sheet PYRS *A 2758370 VSO 09/01/2009 Updated the part# from CYX01XXBB to CYUSB3011-BZXI Changed the title from “ADVANCE” to “ADVANCE INFORMATION” In page 1, the second bullet (Flexible Host Interface), add “32-bit, 100 MHz” to first sub bullet. In page 1, changed the second bullet “Flexible Host Interface” to General Programmable Interface”. In page 1, the second bullet (Flexible Host Interface), removed "DMA Slave Support” and "MMC Slave support with Pass through Boot" sub bullets. In page 1, third bullet, changed "50 A with Core Power" to "60 A with Core Power" In page 1, fifth bullet, added "at 1 MHz" In page 1, seventh bullet, added "up to 4MHz" to UART In page 1, Applications Section, move “Digital Still Cameras” to second line. In page 1, Applications Section, added “Machine Vision” and Industrial Cameras” Added ™ to GPIF and FX3. In page 1, updated Logic Block Diagram. In page 2, section of “Functional Overview”, updated the whole section. In page 2, removed the section of “Product Interface” In page 2, removed the section of “Processor Interface (P-Port)” In page 2, removed the section of “USB Interface (U-Port)” In page 2, removed the section of “Other Interfaces” In page 2, added a section of "GPIF II" In page 2, added a section of "CPU" In page 2, added a section of "JTAG Interface" In page 2, added a section of "Boot Options" In page 2, added a section of "ReNumeration" In page 2, added a section of "Power" In the section of “Package”, replaced “West Bridge USB 3.0 Platform” by FX3. In the section of “Package”, added 0.8 mm pitch in front of BGA. Added Pin List (Table 1) *B 2779196 VSO/PYRS 09/29/2009 Features: Added the thrid bullet “Fully accessible 32-bit ARM9 core with 512kB of embedded SRAM” Added the thrid line “EZ USB™ Software and DVK for easy code development” Table 1: Pin 74, corrected to NC - No Connect. Changed title to EZ-USB™ FX3: SuperSpeed USB Controller *C 2823531 OSG 12/08/2009 Added data sheet to the USB 3.0 EROS spec 001-51884. No technical updates. *D 3080927 OSG 11/08/2010 Changed status from Advance to Preliminary Changed part number from CYUSB3011 to CYUSB3014 Added the following sections: Power, Digital I/Os, Digital I/Os, System-level ESD, Electrical Specifications, AC Timing Parameters, Reset Sequence, Package Diagram Added DC Specifications table Updated feature list Updated Pin List Added support for selectable clock input frequencies. Updated block diagram Updated part number Updated package diagram Document Number: 001-52136 Rev. *S Page 50 of 53 CYUSB301X/CYUSB201X Document History Page (continued) Document Title: CYUSB301X/CYUSB201X, EZ-USB® FX3: SuperSpeed USB Controller Document Number: 001-52136 Orig. of Submission Revision ECN Description of Change Change Date *E 3204393 OSG 03/24/2011 *F *G *H 3219493 3235250 3217917 OSG GSZ OSG 04/07/2011 04/20/2011 04/06/2011 *I *J 3305568 3369042 DSG OSG 07/07/2011 12/06/2011 *K *L 3534275 3649782 OSG OSG 02/24/2012 08/16/2012 *M 3848148 OSG 12/20/2012 *N 4016006 OSG 05/31/2013 Document Number: 001-52136 Rev. *S Updated Slave FIFO protocol and added ZLP signaling protocol Changed GPIFII asynchronous tDO parameter Changed Async Slave FIFO tOE parameter Changed Async Slave FIFO tRDO parameter Added tCOE parameter to GPIFII Sync mode timing parameters Renamed GPIFII Sync mode tDO to tCO and tDO_ss0 to tCO_ss0 Modified description of GPIFII Sync tCO (previously tDO) parameter Changed tAH(address hold time) parameter in Async Slave FIFO modes to be with respect to rising edge of SLWR#/SLRD# instead of falling edge. Correspondingly, changed the tAH number. Removed 24 bit data bus support for GPIFII. Minor ECN - Release to web. No content changes. Minor updates in Features. Updated GPIFII Synchronous Timing diagram. Added SPI Boot option. Corrected values of R_USB2 and R_USB3. Corrected TCK and TRST# pull-up/pull-down configuration. Minor updates to block diagrams. Corrected Synchronous Slave FIFO tDH parameter. Minor ECN - Correct ECN number in revision *F. No content changes. Changed datasheet status from Preliminary to Final. Changed tWRPE parameter to 2ns Updated tRR and tRPW for crystal input Added clarification regarding IOZ and IIX Updated Sync SLave FIFO Read timing diagram Updated SPI timing diagram Removed tGRANULARITY parameter Updated I2S Timing diagram and tTd parameter Updated 121-ball BGA package diagram. Added clarification regarding VCC in DC Specifications table In Power Modes description, stated that VIO1 cannot be turned off at any time if the GPIFII is used in the application Updated Absolute Maximum Ratings Added requirement for by-pass capacitor on U3RXVDDQ and U3TXVDDQ Updated tPEI parameter in Async Slave FIFO timing table Updated Sync Slave FIFO write and read timing diagrams Updated I2C interface tVD:ACK parameter for 1MHz operation Clarified that CTL[15] is not usable as a GPIO Corrected typo in the block diagram. Changed part number to CYUSB301X. Added 256 KB range for embedded SRAM. Updated Functional Overview, Other Interfaces, and Clocking sections. Added Pin List for CYUSB3011 and CYUSB3013 parts. Updated Ordering Information with new part numbers. Updated 121-ball BGA package diagram to current revision. Updated Features (Added 131-ball WLCSP under Package option). Updated Pin Configurations (Added FX3 131-ball WLCSP Ball Map (Figure 7)). Updated Pin Description (Updated Table 7). Updated Electrical Specifications (Included Commercial Temperature Range related information). Updated Operating Conditions (Included Commercial Temperature Range related information). Updated Package Diagram (Added 131-ball WLCSP Package Diagram (Figure 32)). Updated Ordering Information (Updated part numbers). Page 51 of 53 CYUSB301X/CYUSB201X Document History Page (continued) Document Title: CYUSB301X/CYUSB201X, EZ-USB® FX3: SuperSpeed USB Controller Document Number: 001-52136 Orig. of Submission Revision ECN Description of Change Change Date *O 4368374 RSKV 05/02/2014 Updated Package Diagram: spec 001-62221 – Changed revision from *B to *C. Updated to new template. Completing Sunset Review. *P *Q 4474200 4668496 ANOP DBIR 08/14/2014 02/24/2015 Added CYUSB201x MPNs, ball map, and pin list to the datasheet. Updated Features. Updated Logic Block Diagram. Added related documentation hyperlink in page 1. Added More Information. Updated Functional Overview: Updated Application Examples: Updated Figure 1. Updated Figure 2. Updated USB Interface: Updated description. Removed Figure “USB Interface Signals”. Updated Pin Configurations: Updated Figure 6. Updated Reset: Updated Hard Reset: Updated description. Updated Pin Description: Updated Table 7: Updated entire table. Modified CVDDQ power domain description. Removed Table “CYUSB3011 and CYUSB3013 Pin List (GPIF II with 16-bit Data Bus Width)”. Removed Table “CYUSB2014 Pin List (GPIF II with 32-bit Data Bus Width)”. Updated Electrical Specifications: Updated DC Specifications: Added ISS parameter and its details. Updated Slave FIFO Interface: Updated Synchronous Slave FIFO Read Sequence Description: Updated Figure 12. Updated Synchronous Slave FIFO Write Sequence Description: Updated Figure 13. Updated Table 11. Updated AC Timing Parameters: Added Host Processor Interface (P-Port) Timing. Updated Acronyms. Added Errata. Replaced West Bridge Benicia with FX3. *R 4703347 AMDK 03/27/2015 Updated Slave FIFO Interface: Updated Synchronous Slave FIFO Read Sequence Description: Updated Figure 12. Updated Synchronous Slave FIFO Write Sequence Description: Updated Figure 13. Updated Table 11: Updated minimum value of tSSD parameter. Added tACCD, tFAD parameters and their details. *S 5160624 AJAI 04/07/2016 Removed ISS parameter. Added item 6 in Errata. Document Number: 001-52136 Rev. *S Page 52 of 53 CYUSB301X/CYUSB201X 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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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, 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: 001-52136 Rev. *S ® Revised April 7, 2016 Page 53 of 53 EZ-USB™ is a trademark and West Bridge is a registered trademark of Cypress Semiconductor Corp. All products and company names mentioned in this document may be the trademarks of their respective holders.