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CAN bus physical layer structure based on 1XN passive optical splitter (POS)

A technology of CAN bus and splitter, applied in the field of communication, to achieve the best anti-electromagnetic interference characteristics, wide network geographical distribution, and the effect of increasing the maximum transmission rate

Inactive Publication Date: 2012-11-21
蒋涵民
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0005] Aiming at the problems existing in the background technology, the present invention introduces the concept of optical fiber transmission point-to-multipoint into the optical fiber CAN bus, and proposes a CAN bus physical layer system based on a 1×N passive optical splitter, which solves many complex problems in one fell swoop. question

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  • CAN bus physical layer structure based on 1XN passive optical splitter (POS)
  • CAN bus physical layer structure based on 1XN passive optical splitter (POS)
  • CAN bus physical layer structure based on 1XN passive optical splitter (POS)

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Embodiment 1

[0029] Embodiment 1: as figure 2 As shown, the CAN bus physical layer system based on 1×N passive optical splitter of the present invention is sequentially a bus state broadcast unit, a passive one-to-many transmission network, and some CAN nodes from top to bottom. Connections can be made using single or dual fibers. The function of the bus status broadcasting unit is to obtain the bus status belonging to all CAN nodes, and then send the bus status of the CAN nodes to all CAN nodes. The DL port of the bus broadcasting unit is connected to the UL port of the one-to-many transmission network. The bus broadcasting unit receives the uplink optical signal from the DL port, copies it into a downlink optical signal, and then transmits it downward through the DL port. Its reproduction method can be active or passive. The specific connection method is as follows: the downlink optical port DL (DOWN LINK) of the bus state broadcast unit is connected to the uplink optical port UL (UP LI...

Embodiment 2

[0033] Embodiment 2: When the passive one-to-many transmission network cannot handle the scale or distance of CAN nodes, an active relay can be introduced. Such as image 3 As shown, the CAN bus physical layer system based on 1×N passive optical splitter of another embodiment of the present invention is the bus state broadcast unit, one-to-many transmission network 1, active relay, one-to-one Multi-transport network 2 as well as some CAN nodes. Such as image 3 As shown, the one-to-many transport network 1 is at the top layer. Other structures are the same as those described in Embodiment 1, except that there are more active relays between two one-to-many transmission networks. Such as image 3 As shown, the active relay is between the one-to-many transport network 1 and the one-to-many transport network 2 . That is, between the downlink optical port DL of the one-to-many transmission network 1 and the uplink optical port UL of the one-to-many transmission network 2 . An...

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Abstract

The invention discloses a CAN bus physical layer structure based on a 1XN passive optical splitter (POS), comprising a bus state broadcasting unit, a pair of multi-transport networks and a plurality of CAN nodes, which are sequentially connected by optical fibers; the bus state broadcasting unit comprises a lower connective light port and is used for reproducing uplink signals in the CAN bus intodownlink signals; a pair of multi-transport networks comprise single or cascaded 1XN POS and are used for transporting the uplink signals and downlink signals; the CAN node comprises a CAN controllerand an optical fiber transceiving unit. The CAN bus physical layer structure has excellent anti-electromagnetic interference characteristic and wider network area distribution, and simultaneously improves transmission rate greatly.

Description

technical field [0001] The invention belongs to the communication field, and in particular relates to a CAN bus physical layer system based on a passive optical fiber network, which can be widely used in the interconnection of electronic equipment in automobiles, interconnection of household appliances, industrial field control and remote industrial equipment interconnection. Background technique [0002] CAN bus is a mature industrial bus widely used in industrial control and automotive electronics. In the CAN bus specification, only the object layer and the transfer layer are defined. The widely used physical layer structure is metal twisted pair, such as figure 1 shown. Multiple nodes are connected to the CAN bus, and each node includes a CAN controller and a driver chip. The CAN controller can be a separate control chip controlled by an external MCU, or it can itself be an MCU containing CAN controller logic. The role of the driver chip is to switch between the logic...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): H04L12/40H04B10/20H04B10/12H04B10/278
Inventor 蒋涵民
Owner 蒋涵民
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