P80C592FFA NXP Semiconductors, P80C592FFA Datasheet - Page 54
P80C592FFA
Manufacturer Part Number
P80C592FFA
Description
Manufacturer
NXP Semiconductors
Datasheet
1.P80C592FFA.pdf
(108 pages)
Specifications of P80C592FFA
Cpu Family
80C
Device Core
80C51
Device Core Size
8b
Frequency (max)
16MHz
Interface Type
CAN/UART
Program Memory Type
ROMLess
Program Memory Size
Not Required
Total Internal Ram Size
512Byte
# I/os (max)
40
Number Of Timers - General Purpose
3
Operating Supply Voltage (typ)
5V
Operating Supply Voltage (max)
5.5V
Operating Supply Voltage (min)
4.5V
On-chip Adc
8-chx10-bit
Instruction Set Architecture
CISC
Operating Temp Range
-40C to 85C
Operating Temperature Classification
Industrial
Mounting
Surface Mount
Pin Count
68
Package Type
PLCC
Lead Free Status / Rohs Status
Compliant
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Philips Semiconductors
13.5.20.1 Synchronization Rules
The synchronization rules are as follows:
13.6
13.6.1
The P8xC592's CAN-controller supports the four different
CAN-protocol frame types for communication:
13.6.1.1
There are two logical bit representations used in the
CAN-protocol:
1996 Jun 27
Only one synchronization within one bit time is used.
An edge is used for synchronization only if the value
detected at the previous sample point differs from the
bus value immediately after the edge.
Hard synchronization is performed whenever there is a
recessive-to-dominant edge during Bus-Idle
(see Section 13.6.6).
All other edges (recessive-to-dominant and optionally
dominant-to recessive edges if the Sync bit is set HIGH
(see Section 13.5.3) which are candidates for
resynchronization will be used with the following
exception:
– A transmitting CAN-controller will not perform a
Data Frame, to transfer data
Remote Frame, request for data
Error Frame, globally signal a (locally) detected error
condition
Overload Frame, to extend delay time of subsequent
frames (an Overload Frame is not initiated by the
P8xC592 CAN-controller).
A recessive bit on the bus-line appears only if all
connected CAN-controllers send a recessive bit at that
moment.
Dominant bits always overwrite recessive bits i.e. the
resulting bit level on the bus-line is dominant.
8-bit microcontroller with on-chip CAN
resynchronization as a result of a
recessive-to-dominant edge with positive phase
error, if only these edges are used for
resynchronization. This ensures that the delay times
of the output driver and input comparator do not
cause a permanent increase in the bit time.
CAN 2.0A Protocol description
F
RAME TYPES
Bit representation
54
13.6.2
A Data Frame carries data from a transmitting
CAN-controller to one or more receiving ones.
A Data Frame is composed of seven different bit-fields:
13.6.2.1
Signals the start of a Data Frame or Remote Frame.
It consists of a single dominant bit use for hard
synchronization of a CAN-controller in receive mode.
13.6.2.2
Consists of the message Identifier and the RTR bit. In the
case of simultaneous message transmissions by two or
more CAN-controllers the bus access conflict is solved by
bit-wise arbitration, which is active during the transmission
of the Arbitration Field.
13.6.2.3
This 11-bit field is used to provide information about the
message, as well as the bus access priority. It is
transmitted in the order ID.10 to ID.0 (LSB). The situation
that the seven most significant bits (ID.10 to ID.4) are all
recessive must not occur.
An Identifier does not define which particular
CAN-controller will receive the frame because a CAN
based communication network does not differentiate
between a point-to-point, multicast or broadcast
communication.
Start-Of-Frame
Arbitration Field
Control Field
Data Field (may have a length of zero)
CRC Field (CRC = Cyclic Redundancy Code)
Acknowledge Field
End-Of-Frame.
D
ATA
Start-Of-Frame bit
Arbitration Field
Identifier
F
RAME
Product specification
P8xC592
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