MCF5253VM140J Freescale Semiconductor, MCF5253VM140J Datasheet - Page 553

MCF5253VM140J

Manufacturer Part Number

MCF5253VM140J

Description

IC MCU 2.1MIPS 140MHZ 225MAPBGA

Manufacturer

Freescale Semiconductor

Series

MCF525xr

Datasheets

1.MCF5253VM140J.pdf (34 pages)

2.MCF5253VM140J.pdf (8 pages)

3.MCF5253VM140J.pdf (648 pages)

4.MCF5253VM140J.pdf (2 pages)

Specifications of MCF5253VM140J

Core Processor

Coldfire V2

Core Size

32-Bit

Speed

140MHz

Connectivity

CAN, EBI/EMI, I²C, QSPI, UART/USART, USB OTG

Peripherals

DMA, WDT

Program Memory Type

ROMless

Ram Size

128K x 8

Voltage - Supply (vcc/vdd)

1.08 V ~ 1.32 V

Data Converters

A/D 6x12b

Oscillator Type

External

Operating Temperature

-20°C ~ 70°C

Package / Case

225-MAPBGA

Processor Series

MCF525x

Core

ColdFire V2

3rd Party Development Tools

JLINK-CF-BDM26, EWCF

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Number Of I /o

Eeprom Size

Program Memory Size

Lead Free Status / Rohs Status

Details

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Quantity

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If the PID Code indicates an IN, then any of following responses are expected:

If the PID Code indicates an OUT/SETUP, then any of following responses are expected:

24.9.12.2 Split Transaction Interrupt

Split-transaction Interrupt-IN/OUT endpoints are managed using the same data structures used for

high-speed interrupt endpoints. They both co-exist in the periodic schedule. Queue heads/qTDs offer the

set of features required for reliable data delivery, which is characteristic to interrupt transfer types. The

split-transaction protocol is managed completely within this defined functional transfer framework. For

example, for a high-speed endpoint, the host controller will visit a queue head, execute a high-speed

transaction (if criteria are met) and advance the transfer state (or not) depending on the results of the entire

transaction. For low- and full-speed endpoints, the details of the execution phase are different (that is, takes

more than one bus transaction to complete), but the remainder of the operational framework is intact.

24.9.12.2.1 Split Transaction Scheduling Mechanisms for Interrupt

Full- and low-speed Interrupt queue heads have an EPS field indicating full- or low-speed and have a

non-zero S-mask field. The host controller can detect this combination of parameters and assume the

endpoint is a periodic endpoint. Low- and full-speed interrupt queue heads require the use of the split

transaction protocol. The host controller sets the Endpoint Type (ET) field in the split token to indicate the

transaction is an interrupt. These transactions are managed through a transaction translator's periodic

pipeline. The software should not set these fields to indicate the queue head is an interrupt unless the queue

head is used in the periodic schedule.

The system software manages the per/transaction translator periodic pipeline by budgeting and scheduling

exactly during which micro-frames the start-splits and complete-splits for each endpoint will occur. The

characteristics of the transaction translator are such that the high-speed transaction protocol must execute

during explicit micro-frames, or the data or response information in the pipeline is lost.

illustrates the general scheduling boundary conditions that are supported by the EHCI periodic schedule

and queue head data structure. The S and C

start-splits and complete splits (respectively).

Freescale Semiconductor

•

DATA0/1. On reception of data, the host controller ensures the PID matches the expected data

toggle and checks CRC. If the packet is good, the host controller advances the state of the transfer

(for example, moves the data pointer by the number of bytes received, decrements the

BytesToTransfer field by the number of bytes received, and toggles the dt bit). The host controller

then exits this state. The response and advancement of transfer may trigger other processing events,

such as retirement of the qTD and advancement of the queue.

If the data sequence PID does not match the expected, the data is ignored, the transfer state is not

advanced and this state is exited.

ACK. The target endpoint accepted the data, so the host controller must advance the state of the

transfer. The Current Offset field is incremented by Maximum Packet Length or Bytes to Transfer,

whichever is less. The Bytes To Transfer field is decremented by the same amount and the data

toggle bit (dt) is toggled. The host controller then exits this state.

Advancing the transfer state may cause other processing events such as retirement of the qTD and

advancement of the queue.

MCF5253 Reference Manual, Rev. 1

labels indicate micro-frames where the software can schedule

Universal Serial Bus Interface

Figure 24-53

24-91

MCF5253VM140J Freescale Semiconductor, MCF5253VM140J Datasheet - Page 553

MCF5253VM140J

Specifications of MCF5253VM140J

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