hi-3111pstf Holt Integrated Circuits, Inc., hi-3111pstf Datasheet - Page 7

hi-3111pstf

Manufacturer Part Number

hi-3111pstf

Description

Avionics Can Controller With Integrated Transceiver

Manufacturer

Holt Integrated Circuits, Inc.

Datasheet

1.HI-3111PSTF.pdf (51 pages)

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binary value of this 4-bit field specifies the number of data

bytes in the data payload (0 - 8 bytes).

combinations greater than or equal to <1 0 0 0> specify 8

bytes of data.

The remaining fields of the extended data frame (Data field,

CRC field, acknowledge field, EOF field and IFS field) are

constructed in the same way as the standard frame format.

REMOTE FRAME

The remote frame is shown in figure 4. The function of

remote frames is to allow a receiver which periodically

receives certain types of data to request that data from the

transmitting source. The identifier of the remote frame must

be identical to the identifier of the requested transmitting

node’s data frame and the data length code (DLC) should be

equal to the DLC of the requested data.

transmission of remote frames with the same identifier

and different DLCs will lead to unresolvable collisions

on the bus.

discourages the use of remote frames.

The format of a remote frame is identical to the format of the

corresponding data frame except the remote frame has no

data payload.

distinguished by a recessive RTR bit in the remote frame.

This means if a receiver sends a remote frame and the

sending node transmits at the same time, the sending node

(with a dominant RTR bit) will win arbitration and the

requesting node will receive the desired data immediately.

ERROR FRAME

The error frame is shown in figure 5. Any node detecting an

error generates an error frame. The error frame consists of

two fields, the error flag field and the error delimiter. The

type of error flag field depends on the error status of the

node, error-active or error-passive (see below). An error-

active node generates an active error flag and an error-

passive node generates a passive error flag.

Active Error Flag:

consecutive dominant bits. This condition violates the rule

of bit-stuffing and causes all other nodes on the bus to

generate error flags, known as echo error flags. Therefore,

the error flag field will consist of the superposition of different

error flags sent by individual nodes, resulting in a minimum

of 6 and maximum of 12 consecutive dominant bits. The

error flag field is followed by the error delimiter, consisting of

8 recessive bits.

Passive Error Flag:

recessive bits. This is followed by the 8 recessive bits of the

error delimiter. Therefore, an error frame sent by an error-

passive node consists of 14 consecutive recessive bits.

Since this will not disturb the bus, a transmitting node will

continue to transmit unless it detects the error itself, or

another error-active node detects the error.

For this reason, ARINC 825 strongly

Remote frames and data frames are

An active error flag consists of 6

A passive error flag consists of 6

Note:

HOLT INTEGRATED CIRCUITS

Simultaneous

All binary

HI-3110

Notes:

cannot prevail over any other activity on the bus. Therefore,

it must wait for 6 consecutive bits of equal polarity before

completing the error flag.

generated by a transmitter, the bit stuffing rule is violated and

it will cause other nodes to generate error flags.

exceptions to this rule are

a) the passive error flag starts during arbitration and another

node prevails and begins transmitting, and

b) the error flag starts less than 6 bits before the end of the

CRC sequence and the last bits of the CRC sequence all

happen to be recessive.

OVERLOAD FRAME

The overload frame is shown in figure 6. It has the same

format as the active error frame, consisting of an overload

flag field and an overload delimiter.

consists of 6 consecutive dominant bits. This condition

violates the rule of bit-stuffing and causes all other nodes on

the bus to generate echo flags, similar to the active error flag

echos. Therefore, the overload flag field will consist of the

superposition of different overload flags sent by individual

nodes, resulting in a minimum of 6 and maximum of 12

consecutive dominant bits. The overload flag is followed by

the overload delimiter, consisting of 8 recessive bits.

An overload frame, unlike an error frame, can only be

generated during the interframe space. There are two types

of overload frame:

1) Reactive Overload Frame

a) detection of a dominant bit during the first or second bit of

intermission,

b) detection of a dominant bit at the last (seventh) bit of EOF

in received frames, or

c) detection of a dominant bit at the last (eighth) bit of an error

delimiter or overload delimiter.

The reactive overload frame is started one bit after detecting

any of the above dominant bit conditions.

2) Requested Overload Frame.

begin reception of the next message due to internal

conditions may request a delay by transmitting a maximum

of two consecutive overload frames.

overload frame must be started at the first bit of an expected

intermission.

Note 1):

unless reacting to one of the conditions in case 1) above.

Note 2):

825 since they increase the network loading.

If the passive error flag is generated by a receiver, it

Initiation of overload frames is prohibited by ARINC

The HI-3110 will never initiate an overload frame

, resulting from

If the passive error flag is

A node which is unable to

The overload flag

The requested

Two

hi-3111pstf Holt Integrated Circuits, Inc., hi-3111pstf Datasheet - Page 7

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