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4 udc hardware connection, 1 self-powered device, 4 udc hardware connection -10 – Intel PXA255 User Manual

Page 412: 1 self-powered device -10

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12-10

Intel® PXA255 Processor Developer’s Manual

USB Device Controller

The direction of the endpoints is fixed. Physically, the UDC only supports interrupt endpoints with

a maximum packet size of 8 bytes or less, bulk endpoints with a maximum packet size of 64 bytes

or less, and isochronous endpoints with a maximum packet size of 256 bytes or less.

To make the processor more adaptable, the UDC supports a total of four configurations. Each of

these configurations are identical in the UDC, software can make three distinct configurations,

each with two interfaces. Configuration 0 is a default configuration of Endpoint 0 only and cannot
be defined as any other arrangement.

After the host completes a SET_CONFIGURATION or SET_INTERFACE command, the
software must decode the command to empty the OUT endpoint FIFOs and allow the Megacell to

set up the proper power/peripheral configurations.

12.4

UDC Hardware Connection

This section explains how to connect the USB interface for a variety of devices.

12.4.1

Self-Powered Device

Figure 12-2

shows how to connect the USB interface for a self-powered device. The 0

Ω resistors

are optional and if they are not used, USB D+ must connect directly to the device UDC D+ and

connect USB D- must connect directly to the device UDC D-. The UDC D+ and UDC D- pins are

designed to match the impedance of a USB cable, 90

Ω, without external series resistors. To allow

minor impedance corrections to compensate for the impedance that results from the board trace,
0

Ω resistors are recommended on the board.

The “5 V to 3.3 V” device is required because the input pins of the processor can only tolerate 3.3

V. The device can be implemented in a number of ways. The most robust and expensive solution is
a Power-On-Reset device such as a MAX6348. This solution produces a clean signal edge and

minimizes signal bounce. A more inexpensive solution is a 3.3 V line buffer with inputs that can

tolerate 5 V. This solution does not reduce signal bounce, so software must compensate by reading

the GPIO repeatedly until it proves to be stable. A third solution is a signal bounce minimization
circuit that can tolerate 5 V but produces a 3.3 V signal to the GPIO pin.