Cypress CY7C68053 manual Reset and Wakeup, Reset Timing Values, Condition

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CY7C68053

Figure 3-2. Reset Timing Plots

RESET#

RESET#

 

VIL

 

1.8V

 

1.62V

VCC

VCC

 

0V

 

TRESET

Power on Reset

VIL

1.8V

0V

TRESET

Powered Reset

3.9Reset and Wakeup

The reset and wakeup pins are described in detail in this section.

3.9.1Reset Pin

The input pin, RESET#, resets the FX2LP18 when asserted. This pin has hysteresis and is active LOW. When a crystal is used with the CY7C68053, the reset period must allow for the stabilization of the crystal and the PLL. This reset period must be approximately 5 ms after VCC has reached 3.0V. If the crystal input pin is driven by a clock signal the internal PLL stabilizes in 200 s after VCC has reached 3.0V[2]. Figure 3-2shows a power on reset condition and a reset applied during operation. A power on reset is defined as the time reset is asserted while power is being applied to the circuit. A powered reset is defined to be when the FX2LP18 has previously been powered on and operating and the RESET# pin is asserted.

Cypress provides an application note which describes and recommends power on reset implementation and can be found on the Cypress web site. For more information on reset imple- mentation for the MoBL-USB™ family of products, visit the Cypress web site at http://www.cypress.com.

The FX2LP18 exits the power-down (USB suspend) state using one of the following methods:

USB bus activity (if D+/D– lines are left floating, noise on these lines may indicate activity to the FX2LP18 and initiate a wakeup)

External logic asserts the WAKEUP pin

External logic asserts the PA3/WU2 pin

The second wakeup pin, WU2, can also be configured as a general purpose IO pin. This allows a simple external R-C network to be used as a periodic wakeup source. Note that WAKEUP is by default active LOW.

3.9.3Lowering Suspend Current

Good design practices for CMOS circuits dictate that any unused input pins must not be floating between VIL and VIH. Floating input pins will not damage the chip, but can substan- tially increase suspend current. To achieve the lowest suspend current, any unused port pins must be configured as outputs. Any unused input pins must be tied to ground. Some examples of pins that need attention during suspend are:

Port pins. For Port A, B, D pins, extra care must be taken in shared bus situations.

Table 3-3. Reset Timing Values

— Completely unused pins must be pulled to VCC_IO or

 

GND.

Condition

TRESET

Power on Reset with crystal

5 ms

 

 

Power on Reset with external

200 s + Clock stability time

clock

 

Powered Reset

200 s

 

 

3.9.2Wakeup Pins

The 8051 puts itself and the rest of the chip into a power-down mode by setting PCON.0 = 1. This stops the oscillator and PLL. When WAKEUP is asserted by external logic, the oscillator restarts, after the PLL stabilizes, and then the 8051 receives a wakeup interrupt. This applies whether or not FX2LP18 is connected to the USB.

Note

In a single-master system, the firmware must output en- able all the port pins and drive them high or low, before FX2LP18 enters the suspend state.

In a multi-master system (FX2LP18 and another proces- sor sharing a common data bus), when FX2LP18 is sus- pended, the external master must drive the pins high or low. The external master may not let the pins float.

CLKOUT. If CLKOUT is not used, it must be tri-stated during normal operation, but driven during suspend.

IFCLK, RDY0, RDY1. These pins must be pulled to VCC_IO or GND or driven by another chip.

CTL0-2. If tri-stated via GPIFIDLECTL, these pins must be pulled to VCC_IO or GND or driven by another chip.

RESET#, WAKEUP#. These pins must be pulled to VCC_IO or GND or driven by another chip during suspend.

2.If the external clock is powered at the same time as the CY7C680xx and has a stabilization wait period, it must be added to the 200 s.

Document # 001-06120 Rev *F

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Contents Cypress Semiconductor Corporation CY7C68053 FeaturesBlock Diagram Applications USB Signaling SpeedFunctional Overview 8051 MicroprocessorBus-powered Applications USB Boot MethodsI2C Bus BusesPriority INT2VEC Value Source INT2 USB InterruptsCondition Reset and WakeupReset Timing Values Endpoint RAM Program/Data RAMRegister Addresses Default Full-Speed Alternate Settings3 Default Full-Speed Alternate SettingsGpif Default High-Speed Alternate Settings3External Fifo Interface USB Uploads and Downloads Autopointer AccessECC Generation6 18 I2C ControllerPin Assignments 18.2 I2C Interface Boot Load Access18.3 I2C Interface General Purpose Access CY7C68053 56-pin Vfbga Pin Assignment Top view CY7C68053 Pin Descriptions Name Type Default DescriptionFX2LP18 Pin Descriptions Port aFIFOADR1 FIFOADR0Pktend SLCS#Slwr IFCONFIG10 Slrd IFCONFIG10Flaga IFCONFIG10 Flagb IFCONFIG10Ground FX2LP18 Register Summary Register SummaryCOL5 COL4 COL3 COL2 COL1 COL0 LINE17 LINE16 ECC1B2ECC2B0 ECC2B1Epie Qenable Qstate QSIGNAL2 QSIGNAL1 QSIGNAL0EP8 EP6 EP4 EP2 EP1OUT EP1IN EP0OUT EP0IN Gpifwf GpifdoneBusy Stall EP1OUTCSEP1INCS EP2CSTC9 TC8 E6CFTC7 TC6 TC5 TC4 TC3 TC2 TC1 TC0 EP2GPIFFLGSELDPL0 AutoptrsetupDPH0 SELRCAP2H RCAP2LTL2 TH2Operating Conditions Absolute Maximum RatingsDC Characteristics USB Transceiver AC Electrical CharacteristicsGpif Synchronous Signals Slave Fifo Synchronous Read Slave Fifo Synchronous Read Timing Diagram17Slave Fifo Asynchronous Read Slave Fifo Asynchronous Read Timing Diagram17Slave Fifo Synchronous Write Slave Fifo Synchronous Write Timing Diagram17Slave Fifo Synchronous Packet End Strobe Slave Fifo Asynchronous WriteSlave Fifo Asynchronous Packet End Strobe Slave Fifo Synchronous Write Sequence and Timing DiagramSlave Fifo Address to Flags/Data Slave Fifo Output EnableSlave Fifo Asynchronous Address Slave Fifo Synchronous AddressSingle and Burst Synchronous Read Example Sequence DiagramIfclk Sloe SlrdSingle and Burst Synchronous Write 17. Slave Fifo Asynchronous Read Sequence of Events Diagram Sequence Diagram of a Single and Burst Asynchronous ReadSequence Diagram of a Single and Burst Asynchronous Write Development Tool Kit Package DiagramOrdering Information PCB Layout Recommendations Document History Issue Date Orig. Description of ChangeOSG ARI

CY7C68053 specifications

The Cypress CY7C68053 is a versatile USB microcontroller known for its strong performance and rich feature set, catering to a wide range of applications requiring USB connectivity. Part of the Cypress family of USB products, this microcontroller combines the convenience of USB interfacing with powerful embedded processing capabilities.

At its core, the CY7C68053 is built on an 8051 microcontroller architecture, enabling efficient data handling and control operations. It operates at speeds of up to 48 MHz, providing ample processing power for complex applications. The device features an integrated USB 2.0 full-speed controller, which allows for high-speed data transfer rates of up to 12 Mbps. This makes it ideal for applications such as data transfer, communication devices, and real-time processing tasks.

One of the standout features of the CY7C68053 is its flexible pin configuration. It supports a variety of operating modes, including peripheral mode, host mode, and a combination of both, allowing it to cater to diverse application requirements. Additionally, the device offers a large number of GPIO pins that can be used for various control and communication tasks. This flexibility ensures that developers can tailor the hardware to meet the specific needs of their application.

In terms of development, the CY7C68053 is backed by a robust set of software development tools from Cypress. The EZ-USB development kit provides a comprehensive platform for firmware development, testing, and debugging. This kit includes libraries, example projects, and a user-friendly integrated development environment (IDE), streamlining the development process for engineers.

The CY7C68053 is also equipped with an extensive memory system, featuring 32 kB of in-system programmable Flash memory, 2 kB of SRAM, and 128 bytes of EEPROM. This memory capacity allows for the storage of complex firmware and user data, enhancing the device's versatility.

Moreover, the CY7C68053 is designed with low power consumption in mind. It includes power management features that allow it to operate efficiently, making it suitable for battery-operated devices.

In summary, the Cypress CY7C68053 stands out as a powerful USB microcontroller that combines high-speed processing, flexible configurations, and robust software support. Its features make it an excellent choice for developers looking to create innovative USB-enabled products across various applications.
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