This section lists common problems and possible solutions. If you experience other problems or would like to add a solution for a problem feel free to open an issue in our Github project or send us an email to email@example.com.
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Bitrate-Intolerant CAN Bus
Problem: The host-side CAN-interface sends an error-frame for every CAN packet sent by the Ethernet-Mux.
The CAN-Bus protocol is designed to allow bitrate offsets of a few percent between bus nodes. This is especially relevant when a bus contains nodes without precise crystal-based clock sources. Synchronization is performed on the receiving side of a CAN-frame by monitoring the actual and expected timing of bit transitions seen on the bus, and adjusting the bit-sampling of subsequent bits accordingly.
The generation of CAN-timings is based on a base clock, that is sub-divided
using counters, to determine the sample points for reception and the
signal transition points for sending. These counter timings make use of units of time called
tq, on Linux these time quanta are given in nanoseconds.
One parameter that is specified in terms of time quanta is the synchronization jump
sjw), a parameter determining the maximum amount of bitrate synchronization
performed during reception of a CAN-frame.
Currently SocketCAN initializes every device with a synchronization jump width (
of 1 time quantum.
As the length of a time quantum
tq varies widely between different CAN-controllers
this results in maximum amount of bitrate-synchronization performed by default also
varying widely between CAN-controllers. On some CAN-controllers the amount of synchronization
allowed by the default setup is not sufficient to use LXA IOBus devices, leading to
frames being rejected by the CAN-controller.
Solution: Use a
sjw relative the other bit-timings instead of a fixed value of 1.
LXA IOBus devices are tested at a
sjw of 5% of one bit-time.
To determine the current bit-timings the
can0 interface should first
be configured to the desired bitrate of 100 kbit/s, e.g. by using systemd-networkd.
The resulting bit timings are calculated automatically by the Linux kernel
and can then be displayed using the
$ ip --details link show can0 5: can0: <NOARP,UP,LOWER_UP,ECHO> mtu 16 qdisc pfifo_fast state UP mode DEFAULT group default qlen 10 link/can promiscuity 0 minmtu 0 maxmtu 0 can state ERROR-PASSIVE (berr-counter tx 128 rx 0) restart-ms 100 bitrate 100000 sample-point 0.875 tq 50 prop-seg 87 phase-seg1 87 phase-seg2 25 sjw 1 peak_canfd: tseg1 1..256 tseg2 1..128 sjw 1..128 brp 1..1024 brp-inc 1 peak_canfd: dtseg1 1..32 dtseg2 1..16 dsjw 1..16 dbrp 1..1024 dbrp-inc 1 clock 80000000 numtxqueues 1 numrxqueues 1 gso_max_size 65536 gso_max_segs 65535
Shown in line 6 are the timing-parameters
sjw. One bit-time consists of
1 + prop-seg + phase-seg1 + phase-seg2 time quanta.
sjw should thus be adjusted to a value of
sjw = ⌊0.05 * (1 + prop-seg + phase-seg1 + phase-seg2)⌋ = 10.
The interface can be re-configured accordingly using the command:
$ ip link set can0 type can tq 50 prop-seg 87 phase-seg1 87 phase-seg2 25 sjw 10
All other values but
sjw are copied from the status output above.