EtherCAT Slave Controller Overview
An EtherCAT Slave Controller (ESC) takes care of the EtherCAT communication as an interface
between the EtherCAT fieldbus and the slave application. This document covers the following
Beckhoff ESCs: ASIC implementations (ET1100, ET1200), functionally fixed binary configurations for
FPGAs (ESC20), and configurable IP Cores for FPGAs (ET1810/ET1815).
Table 1: ESC Main Features
|
Feature
|
ET1200
|
ET1100
|
IP Core
|
ESC20
|
|
Ports
|
2-3 (each
EBUS/MII,
max. 1xMII)
|
2-4 (each
EBUS/MII)
|
2-3 MII or
2 RMII
|
2 MII
|
|
FMMUs
|
3
|
8
|
0-8
|
4
|
|
SyncManagers
|
4
|
8
|
0-8
|
4
|
|
RAM [KByte]
|
1
|
8
|
1-60
|
4
|
|
Distributed Clocks
|
64bit
|
64bit
|
32/64bit
|
32bit
|
|
Process Data Interfaces
|
|
Digital I/O
|
16bit
|
32bit
|
8-32bit
|
32bit
|
|
SPI Slave
|
Yes
|
Yes
|
Yes
|
Yes
|
|
8/16 bit μController
|
-
|
Async/Sync
|
Async
|
Async
|
|
On-chip bus
|
-
|
-
|
Avalon/OPB
|
-
|
The general functionality of an ESC is shown in Figure 1:
Figure 1: EtherCAT Slave Controller Block Diagram
EtherCAT Slave Controller Function Blocks
EtherCAT Interfaces (Ethernet/EBUS)
The EtherCAT interfaces or ports 连接 the ESC to 其他 EtherCAT slaves and the master. The
MAC layer is integral part of the ESC. The physical layer may be Ethernet or EBUS. The physical
layer for EBUS is fully integrated into the ASICs. For Ethernet ports, external Ethernet PHYs 连接
to the MII/RMII ports of the ESC. Transmission speed for EtherCAT is fixed to 100 Mbit/s with Full
Duplex communication. Link state and communication status are reported to the Monitoring device.
EtherCAT slaves support 2-4 ports, the logical ports are numbered 0-1-2-3, formerly they were
denoted by A-B-C-D.
EtherCAT Processing Unit
The EtherCAT Processing Unit (EPU) receives, analyses and processes the EtherCAT data stream. It
is logically located between port 0 and port 3. The main purpose of the EtherCAT Processing unit is to
enable and coordinate access to the internal registers and the memory space of the ESC, which can
be addressed both from the EtherCAT master and from the local application via the PDI. Data
ex改变 between master and slave application is comparable to a dual-ported memory (process
memory), enhanced by special functions e.g. for consistency checking (SyncManager) and data
mapping (FMMU). The EtherCAT Processing Units contains the main function blocks of EtherCAT
slaves besides Auto-Forwarding, Loop-back function, and PDI.
Auto-Forwarder
The Auto-Forwarder receives the Ethernet frames, performs frame checking and forwards it to the
Loop-back function. Time stamps of received frames are generated by the Auto-Forwarder.
Loop-back function
The Loop-back function forwards Ethernet frames to the next logical port if there is either no link at a
port, or if the port is not available, or if the loop is closed for that port. The Loop-back function of port 0
forwards the frames to the EtherCAT Processing Unit. The loop settings can be controlled by the
EtherCAT master.
FMMU
Fieldbus Memory Management Units are used for bitwise mapping of logical addresses to physical
addresses of the ESC.
SyncManager
SyncManagers are responsible for consistent data ex改变 and mailbox communication between
EtherCAT master and slaves. The communication direction can be configured for each SyncManager.
Read or write transactions may generate events for the EtherCAT master and an attached μController
respectively.
Monitoring
The Monitoring unit contains error counters and watchdogs. The watchdogs are used for observing
communication and returning to a safe state in case of an error. Error counters are used for error
detection and analysis.
Reset
The integrated reset controller observes the supply voltage and controls external and internal resets
(ET1100 and ET1200 ASICs only).
PHY Management
The PHY Management unit communicates with Ethernet PHYs via the MII management interface. This
is either used by the master or by the slave. The MII management interface is used by the ESC itself
for restarting autonegotiation after receive errors with the enhanced link detection mechanism, and for
the optional MI link detection and configuration feature.
Distributed Clock
Distributed Clocks (DC) allow for precisely synchronized generation of output signals and input
sampling, as well as time stamp generation of events. The synchronization may span the entire
EtherCAT network.
Memory
An EtherCAT slave can have an address space of up to 64Kbyte. The first block of 4 Kbyte (0x0000-
0x0fff) is used for registers and user memory. The memory space from address 0x1000 onwards is
used as the process memory (up to 60 Kbyte). The size of process memory depends on the device.
The ESC address range is directly addressable by the EtherCAT master and an attached μController.
Process Data Interface (PDI) or Application Interface
There are several types of PDIs available, depending on the ESC:
• Digital I/O (8-32 bit, unidirectional/bidirectional, with DC support)
• SPI slave
• 8/16 bit μController (asynchronous or synchronous)
• On-chip bus (e.g., Avalon for Altera FPGAs or OPB for Xilinx FPGAs)
• General purpose I/O
The PDIs are described in Section III of the particular ESC, since the PDI functions are highly
depending on the ESC type.
ESI EEPROM
One non-volatile memory is needed for ESC configuration and device description, typically an I²C
EEPROM. If the ESC is implemented as an FPGA, a second non-volatile memory is necessary for the
FPGA configuration code.
Status / LEDs
The Status block provides ESC and application status information. It controls external LEDs like the
application RUN LED and port Link/Activity LEDs.
ET1100datasheet.pdf (6.6MBytes)
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