Difference between revisions of "Programming the Ethernet controller"

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The modules involved in communication with the Ethernet Controller chip serve as the core of the FPGA. The different tasks that need to be performed by these modules include  
+
The modules involved in communication with the Ethernet Controller chip (EC) serve as the core of the FPGA. The tasks that need to be performed by these modules include  
 
* executing the complex board reset and address lookup sequence
 
* executing the complex board reset and address lookup sequence
 
* polling for new packets and switching execution accordingly
 
* polling for new packets and switching execution accordingly
Line 6: Line 6:
 
* building return packets
 
* building return packets
  
In  our design, the modules involved with packet handling and interfacing with sensor chip controllers are organized by ''state''. A state register specifies the current stage of the process and only the corresponding module is allowed to act during that stage. Aside from defining a process sequence, the state serves as a complex "enable" signal for the modules, ensuring that only one module is driving the communication bus used to query the Ethernet Controller chip.
+
In  our design, the modules involved with packet handling and interfacing with sensor chip controllers are organized by ''state''. A state register specifies the current stage of the process and only the corresponding module is allowed to act during that stage. Aside from defining a process sequence, the state serves as a complex "enable" signal for the modules, ensuring that only one module is driving the communication bus used to query the EC.
 
 
 
 
 
 
= Interface =
 
 
 
:''See also: [[Ethernet packets]]''
 
 
 
[[Image:MuxIntelTiming.png|frame|Multiplexed Intel Bus and internal I/O timing scheme enforced by FPGA clocks]]
 
 
 
The compact approach to wire and poll the Ethernet Controller chop is via the Multiplexed Intel bus format. Aside from some use of the interrupt and reset pins, all communication is done via this bus. (The control architecture of the chip uses 8-bit registers selected with 8-bit addresses.) A communication over this bus begins with an pulse on the "ALE" pin, by the fall of which a valid address is expected on the 8-bit inout "AD" bus. After this /RD (/WR) signal falls, executing the read (write) process, and then rises accompanied with valid input from (to) the chip. The adjacent figure illustrates this process along with the approach to timing the conversation taken in this design. Please refer to Section 16.2 in the manual for details on the timing tolerances on this bus.
 
 
 
As shown in the figure, the 20 MHz clock is very convenient for metering this conversation. The communication delay for the FPGA (most of which runs essentially on 5 MHz) turns out to be only two clock cycles.
 
 
 
= The eight states =
 
 
 
There are eight major states to the module.
 
 
 
== State list ==
 
 
 
; (000) Reset Cycle
 
: The reset cycle resets the selected chips.  There are flags for resetting all 4 chips: DAC, ADC, temperature sensor, Ethernet controller.  This is the entry state from a power-on.  From this state, proceed unconditionally to 001.
 
; <s>(001) Transmit "I"</s>
 
: <s>This state transmits an "I" packet to acknowledge that a reset occurred but the board is now prepared to accept new packets and function normally. From this state, proceed unconditionally to 010.</s> "S"-Packet (from state 101) would do just as well, returning zeroed registers, location address etc for computer's address LUT.
 
; (010) Idle
 
: This is the idle state where the state machine awaits a new packet's arrival.  If the Receive FIFO is empty, it loops back on itself and continues checking the FIFO.  If the FIFO is not empty, proceed to 011.
 
; (011) Read Packet
 
: This state accesses the first packet.  If packets need to be filtered by the FPGA, this state will filter and return to 010 on a bad packet.  The MAC data is discarded, as it is unimportant to the FPGA, and the first data byte is read.  This byte is used as a switch: an ASCII "R" loops to 000.  A "Q" proceeds to 100.  A "P" proceeds to 110.  Any other value is a bad packet and the state machine returns to 010.
 
; (100) Poll Status
 
: This state polls the status chips (the ADC and the temperature sensor) so that recent data is ready for transmission.
 
; (101) Transmit "S"
 
: This state packages and transmits an "S" packet over the Ethernet to report back the status of the board in response to a "Q" packet.
 
; (110) Program DAC
 
: This state programs the DAC with new values according to the mask and data in the "P" packet.
 
; (111) Transmit "D"
 
: This state packages and transmits a "D" packet over the Ethernet to report back the DAC voltages in response to a "P" packet.
 
 
 
== State interconnect ==
 
 
 
These states will form the outline of the functional block diagram.  Within each state will be a smaller process or set of processes, possibly broken into substates.  This implementation calls for a central ''state'' register.  Each block reads the state value in the register and enables itself upon seeing its own value.  After completion of its function, a block will write a new value to the state register to enable the next block. With several modules writing to the register, usual precautions must be taken to avoid more than one drivers forcing a line simultaneously. All modules must be designed to go to high impedance on their output lines when they are not active.
 
 
 
== State variable ==
 
 
 
Based on the assignments of state values to the various states, certain interpretations of the state's bits arise.  They may or may not prove useful in coding the system.  They are given here in the case that they do become useful.
 
* S<sub>2:1</sub>:
 
** S<sub>2</sub> = 0: "Core cycle" that executes regularly and forms the spine of the state diagram.
 
*** S<sub>2:1</sub> = 00: "Initialization cycle" that prepares the state diagram for normal functioning.
 
*** S<sub>2:1</sub> = 01: "Standard cycle" that the state machine returns to most frequently to process appropriate switching to branches.
 
** S<sub>2</sub> = 1: "Branch cycles" that execute selectively based on received packets.
 
*** S<sub>2:1</sub> = 10: "Query cycle" as described in the page on [[Ethernet_packets#The_query_cycle|Ethernet packets]].
 
*** S<sub>2:1</sub> = 11: "Programming cycle" as described in the page on [[Ethernet_packets#The_programming_cycle|Ethernet packets]].
 
* S<sub>0</sub>:
 
** S<sub>0</sub> = 0: "Setup state" to prepare internal workings for a communication.
 
** S<sub>0</sub> = 1: "Transfer state" to communicate with the external PC.
 
 
 
  
 
= Controller =
 
= Controller =
Line 66: Line 12:
 
== Foreword on Timing ==
 
== Foreword on Timing ==
  
With a controller this complex, the timing of signals must be inspected even more scrupulously than usual. In particular, simultaneous transitions of data and "Done" lines must be avoided. When possible, a one-cycle-delayed "Done" signal is used to ensure that the data lines have been stabilized. (All delays are implemented via the <tt>c_delay</tt> module which postpones the signal by one cycle via two sequential flip-flops, each shifting by half-cycle).  When this is inconvenient (e.g. when writing to registers) the target component must not be enabled on rising edges on "Go" or the clock.  The registers, for instance, have been designed to read values on the ''falling edge'' of the clock - middle of the "Go" pulse, safely after the data line transitions.
+
With a controller this complex, the timing of signals must be inspected even more scrupulously than usual. Simultaneity of the rising edge of the "Done" signal and the corresponding output data may not be guaranteed. This is solved by either
 +
# a one-cycle-delayed "Done" signal to ensure that the data lines have been stabilized. (All delays are implemented via the <tt>c_delay</tt> module which postpones the signal by one cycle via two sequential flip-flops, each shifting by half-cycle).   
 +
# coding the target component to read the data lines on the ''falling edge'' of the clock during the a "Go" signal.
 +
The latter method turned out to be the dominant one in this design.
  
 +
== The eight states ==
  
[[FPGA_Transceiver|Transceiver]]
+
=== State-Module organization ===
  
[[FPGA_Reset|Reset Modules]]
+
The core of the the FPGA is divided roughly into eight modules enabled by by the 3-bit state value. Below is an index of the states and their corresponding modules. In this discussion of states, 'X' is a binary wild card the values are immediately explained.
  
[[FPGA_Idler|Idler (Idle Process Module)]]
+
{| class="wikitable" border="1" align="center" style="text-align:center" cellspacing="0" cellpadding="4"
 +
|+ State-Module Index
 +
|-
 +
! State !! Module Name !! Description !! Succeeding State
 +
|-
 +
| align="center" | 000 || [[FPGA_Reset|Reset]]_hard || align="left" |Coordinates the reset and start-up of the EC. || 100
 +
|-
 +
| align="center" | 001 || [[FPGA_Reset|Reset]]_soft || align="left" | Extends the reset to the PC-requested chips and records PC's MAC for later communication. || 100
 +
|-
 +
| align="center" | 010 || [[FPGA_Idler|Idler]] || align="left" | This is the active module during the FPGA's default idle state. It awaits the "Receive FIFO buffer not empty" interrupt and passes control to the Reader || 011
 +
|-
 +
| align="center" | 011 || [Packet] [[FPGA_Reader|Reader]] || align="left" | Skips the packet header and reads the first two bytes ("location" and "type") of the packet payload. It rejects misdirected or invalid-type bytes. Control is passed according to packet type to Query, Program or Reset Modules || 100, 110, 00X
 +
|-
 +
| align="center" | 100 || [[FPGA_Querier|Querier]] || align="left" | Queries the values of the Temperature sensor and ADC, stores them in their respective registers and passes control to the Transmitter for delivery || 101 
 +
|-
 +
| align="center" | 110 || [DAC] [[FPGA_Programmer|Programmer]] || align="left" | Programs the DAC based on instructions in packet and stores the values in the DAC register. || 111
 +
|-
 +
| align="center" | 1X1 || [Packet] [[FPGA_Transmitter|Transmitter]] || align="left" | Composes and sends a packet of either [[Ethernet_packets|'S' or 'D' type]]. These correspond respectively to "'''S'''tatus" values reported by the sensor chips (state=101) and current '''D'''AC values (state=111) || 010
 +
|-
 +
|}
  
[[FPGA_Reader|Packet Reader]] (Packet type inspection)
+
=== State interconnect ===
  
[[FPGA_Querier|Querier (status query module)]]
+
As described above, these states form the outline of the functional block diagram. This implementation calls for a central ''state register''.  Each block reads the state value in the register and enables itself upon seeing its own value.  After completion of its function, a block will write a new value to the state register to enable the next block. With several modules writing to the register, usual precautions must be taken to avoid more than one drivers forcing a line simultaneously. All modules must be designed to go to high impedance on their output lines when they are not active.
  
[[FPGA_Transmitter|Packet Transmitter]]
 
  
 +
== Miscellaneous non-state-based components ==
  
[[FPGA_Registers|Registers]]
+
Please refer to the individual design detail pages for:
 +
* [[FPGA_Registers|Registers]]
 +
* [[FPGA_Reusables|Miscellaneous Reusable Components]]
  
[[FPGA_Reusables|Miscellaneous Reusable Components]]
 
  
 +
== Interface ==
  
 +
[[Image:MuxIntelTiming.png|frame|Multiplexed Intel Bus and internal I/O timing scheme enforced by FPGA clocks]]
  
 +
The compact approach to wire and poll the EC is via the Multiplexed Intel bus format. Aside from some use of the interrupt and reset pins, all communication is done via this bus. (The control architecture of the chip uses 8-bit registers selected with 8-bit addresses.) A communication over this bus begins with an pulse on the "ALE" pin, by the fall of which a valid address is expected on the 8-bit inout "AD" bus. After this /RD (/WR) signal falls, executing the read (write) process, and then rises accompanied with valid input from (to) the chip. The adjacent figure illustrates this process along with the approach to timing the conversation taken in this design. Please refer to Section 16.2 in the manual for details on the timing tolerances on this bus.
  
 +
As shown in the figure, the 20&nbsp;MHz clock is very convenient for metering this conversation. The communication delay for the FPGA (most of which runs essentially on 5&nbsp;MHz) turns out to be only two clock cycles.
  
 +
This communication standard calls for a bridge module that communicates with the EC upon request from other modules. A "[[FPGA_Transceiver|Transceiver]]" was designed for this purpose. It abstracts the communication with the EC as well as the clock frequency difference. This module in fact subdivides the main 20&nbsp;MHz; clock to generate the "slow" 5&nbsp;MHz clock for the rest of the FPGA. Please refer to the [[FPGA_Transceiver|detailed page]] on the Transceiver for more information.
  
  
 +
== Combined control flow ==
  
 +
[[Image:OperationCourse.png|frame|Operation course between the digital board and the controller PC]]
  
== (110) Program DAC ==
+
Conceptually, the operation course must proceed as outlined in the adjacent figure. The main concern in the tagger control is maintaining a map between board/channel addresses and actual energy bins. For this purpose, the diagrammed two-stage reset plan was devised in the course of which the FPGA learns the PC's MAC address and the PC builds a MAC-Location lookup table. (The "Location" is an 8-byte slot identifier which allows the PC to pinpoint the SiPM channel group.)
  
This block will have a substate to obtain the programming mask.  It then loops 32 (or 24 or 16) times on a second substate that obtains the next programming value and, if the corresponding mask bit is high, programs that channel of the DAC.  A mux may be needed to select the appropriate bit from the programming mask.  It also updates the locally stored DAC channel values (which may be stored on the FPGA, the CP2200/1 Flash, or other) in preparation for a "D" response packet.  Then it transitions to state 111.
+
The internal FPGA operation course that supports this scheme (and the general control board functionality requirements) is outlined below.
  
inputs
+
[[Image:DigBoardScheme.png|center]]
* ''Clk'': clock
 
* ''/Rst'': asynchronous, active-low reset
 
* ''State'': 3-bit state value
 
  
internal signals
 
* ''S_En'': state enable, ''S_En'' <= not (''St(2)'' or ''St(1)'' or ''St(0)'')
 
* ''Go'': when ''S_En'' goes high ''Go'' pulses for one cycle
 
  
blocks
+
= Emulator =
* '''Mask Fetcher'''
 
** This block reads the programming mask, contained in the second data byte (first remaining byte) through the 5th/4th/3rd byte (4th/3rd/2nd remaining byte), and saves it into a 32/24/16-bit register.
 
** inputs
 
*** ''Clk'': clock
 
*** ''/Rst'': asynchronous, active-low reset
 
*** ''Go'': pulse to begin, comes from ''Go'' internal signal of block 110
 
*** ''TxRx_D'': 8-bit data bus from transceiver
 
*** ''TxRx_Done'': ''Done'' signal from transceiver
 
** outputs
 
*** ''TxRx_Go'': ''Go'' input on transceiver
 
*** ''TxRx_R/W'': ''R/W'' input on transceiver; tied to read (one)
 
*** ''TxRx_A'': ''A_in'' bus on transceiver
 
*** ''Mask'': 32/24/16-bit readout of programming mask
 
*** ''Done'': pulse to signal that mask has been obtained
 
* '''Programmer'''
 
** Programs the DAC.  Loops 32/24/16 times, obtaining the next byte from the CP2200/1 buffer, checking the mask, programming the DAC if the mask is 1 or skipping if the mask is 0.  Also writes the value to the internal DAC value storage registers (or Flash memory or other).
 
** inputs
 
*** ''Clk'': clock
 
*** ''/Rst'': asynchronous, active-low reset
 
*** ''Go'': pulse to begin; feeds from ''Done'' signal of Mask Fetcher
 
*** ''TxRx_D'': ''D_out'' bus on transceiver
 
*** ''TxRx_Done'': ''Done'' signal on transceiver
 
** outputs
 
*** - DAC control lines -
 
*** ''TxRx_Go'': ''Go'' signal on transceiver
 
*** ''TxRx_R/W'': ''R/W'' signal on transceiver
 
*** ''TxRx_A'': ''A_in'' bus on transceiver
 
*** ''Sel'': 5/5/4-bit select bus to internal registers
 
*** ''Data'': 32/24/16-bit data bus to internal registers
 
*** ''Done'': pulse to signal completion
 
* '''Discarder'''
 
** This block orders the CP2200/1 to discard the packet, now that the FPGA is done with all the data contained within the packet.
 
** inputs
 
*** ''Clk'': clock
 
*** ''/Rst'': asynchronous, active-low reset
 
*** ''Go'': pulse to begin; feeds from ''Done'' signal of Programmer
 
*** ''TxRx_Done'': ''Done'' signal on transceiver
 
** outputs
 
*** ''TxRx_Go'': ''Go'' signal on transceiver
 
*** ''TxRx_R/W'': ''R/W'' signal on transceiver
 
*** ''TxRx_A'': ''A_in'' bus on transceiver
 
*** ''Done'': pulse to signal completion
 
*** ''New_St'': next state to load into the state register; goes to 111 when ''Done'' is high
 
  
== (111) Transmit "D" ==
+
Since the modules described here represent the core of the FPGA, their combined simulation calls for inclusion of all other fringe modules.  Essentially the whole FPGA will have to be tested to ensure this scheme for the core is acting properly. The challenge is in the complexity of the stimulus for such simulation: whole packets will need to be sent in and possibly inter-packet Ethernet Controller Chip states tested.
  
This block loads a "D" to the transmit buffer then loops 32 (or 24 or 16) times to load the locally stored DAC channel values to the transmit buffer. Once the full packet has been loaded, it sends the packet, then transitions to state 010.
+
A stripped down emulator for the Ethernet Controller has been written. It is a essentially a set of registers with a Multiplexed Intel bus communication layer and packet file read/write layers. These registers, however, are not passive memory banks but include "events" that are triggered by particular register states. For instance writing to registers designated to make up a receive buffer pointer actually delivers the requested byte from the buffer to the appropriate control register to be available for a subsequent request. A simple interrupt system (stimulated externally by the simulation layer) has also been included.
 
 
inputs
 
* ''Clk'': clock
 
* ''/Rst'': asynchronous, active-low reset
 
* ''State'': 3-bit state value
 
  
internal signals
 
* ''S_En'': state enable, ''S_En'' <= not (''St(2)'' or ''St(1)'' or ''St(0)'')
 
* ''Go'': when ''S_En'' goes high ''Go'' pulses for one cycle
 
  
blocks
+
= See Also =
* '''Loader'''
 
** Loads the DAC values into a packet in the transmission buffer of the CP2200/1.  Loops through all values and loads them in order (channel zero to channel thirty-one).
 
** inputs
 
*** ''Clk'': clock
 
*** ''/Rst'': asynchronous, active-low reset
 
*** ''Go'': pulse to begin loading a packet
 
*** ''TxRx_Done'': ''Done'' signal on transceiver
 
*** ''Data'': 14-bit data bus from internal registers
 
** outputs
 
*** ''TxRx_Go'': ''Go'' signal on transceiver
 
*** ''TxRx_RW'': ''R/W'' signal on transceiver
 
*** ''TxRx_A'': ''A_in'' bus on transceiver
 
*** ''TxRx_D'': ''D_in'' bus on transceiver
 
*** ''Done'': pulse to signal completion
 
* '''Sender'''
 
** Tells CP2200/1 to send the packet
 
** inputs
 
*** ''Clk'': clock
 
*** ''/Rst'': asynchronous, active-low reset
 
*** ''Go'': pulse to begin, connected to ''Done'' signal from Loader
 
*** ''TxRx_Done'': ''Done'' signal from transceiver
 
** outputs
 
*** ''TxRx_Go'': ''Go'' signal on transceiver
 
*** ''TxRx_RW'': ''R/W'' signal on transceiver
 
*** ''TxRx_A'': ''A_in'' bus on transceiver
 
*** ''TxRx_D'': ''D_in'' bus on transceiver
 
*** ''Done'': pulse to signal completion
 
*** ''New_St'': 3-bit bus of new state to write to state register; goes to 010 when ''Done'' is high
 
  
= Emulator =
+
* State Modules
 +
** [[FPGA_Reset|Reset]]
 +
** [[FPGA_Idler|Idler]]
 +
** [[FPGA_Reader|Reader]]
 +
** [[FPGA_Querier|Querier]]
 +
** [[FPGA_Programmer|Programmer]]
 +
** [[FPGA_Transmitter|Trasmitter]]
  
Since the modules described here represent the core of the FPGA, their combined simulation calls for inclusion of all other fringe modules.  Essentially the whole FPGA will have to be tested to ensure this scheme for the core is acting properly. The challenge is in the complexity of the stimulus for such simulation: whole packets will need to be sent in and possibly inter-packet Ethernet Controller Chip states tested.
+
* Non-state Modules
 +
** [[FPGA_Transceiver|Transceiver]]
 +
** [[FPGA_Interrupt_Catcher|Interrupt Catcher]]
 +
** [[FPGA_Registers|Registers]]
  
A stripped down emulator for the Ethernet Controller has been written. It is a essentially a set of registers with a Multiplexed Intel bus communication layer and packet file read/write layers. These registers, however, are not passive memory banks but include "events" that are triggered by particular register states. For instance writing to registers designated to make up a receive buffer pointer actually delivers the requested byte from the buffer to the appropriate control register to be available for a subsequent request. A simple interrupt system (stimulated externally by the simulation layer) has also been included.
+
* [[Ethernet_packets|Ethernet Packet formatting]]

Latest revision as of 06:33, 5 November 2009

The modules involved in communication with the Ethernet Controller chip (EC) serve as the core of the FPGA. The tasks that need to be performed by these modules include

  • executing the complex board reset and address lookup sequence
  • polling for new packets and switching execution accordingly
  • collecting sensor information upon a status report request
  • programming the DAC upon a program packet receipt
  • building return packets

In our design, the modules involved with packet handling and interfacing with sensor chip controllers are organized by state. A state register specifies the current stage of the process and only the corresponding module is allowed to act during that stage. Aside from defining a process sequence, the state serves as a complex "enable" signal for the modules, ensuring that only one module is driving the communication bus used to query the EC.

Controller

Foreword on Timing

With a controller this complex, the timing of signals must be inspected even more scrupulously than usual. Simultaneity of the rising edge of the "Done" signal and the corresponding output data may not be guaranteed. This is solved by either

  1. a one-cycle-delayed "Done" signal to ensure that the data lines have been stabilized. (All delays are implemented via the c_delay module which postpones the signal by one cycle via two sequential flip-flops, each shifting by half-cycle).
  2. coding the target component to read the data lines on the falling edge of the clock during the a "Go" signal.

The latter method turned out to be the dominant one in this design.

The eight states

State-Module organization

The core of the the FPGA is divided roughly into eight modules enabled by by the 3-bit state value. Below is an index of the states and their corresponding modules. In this discussion of states, 'X' is a binary wild card the values are immediately explained.

State-Module Index
State Module Name Description Succeeding State
000 Reset_hard Coordinates the reset and start-up of the EC. 100
001 Reset_soft Extends the reset to the PC-requested chips and records PC's MAC for later communication. 100
010 Idler This is the active module during the FPGA's default idle state. It awaits the "Receive FIFO buffer not empty" interrupt and passes control to the Reader 011
011 [Packet] Reader Skips the packet header and reads the first two bytes ("location" and "type") of the packet payload. It rejects misdirected or invalid-type bytes. Control is passed according to packet type to Query, Program or Reset Modules 100, 110, 00X
100 Querier Queries the values of the Temperature sensor and ADC, stores them in their respective registers and passes control to the Transmitter for delivery 101
110 [DAC] Programmer Programs the DAC based on instructions in packet and stores the values in the DAC register. 111
1X1 [Packet] Transmitter Composes and sends a packet of either 'S' or 'D' type. These correspond respectively to "Status" values reported by the sensor chips (state=101) and current DAC values (state=111) 010

State interconnect

As described above, these states form the outline of the functional block diagram. This implementation calls for a central state register. Each block reads the state value in the register and enables itself upon seeing its own value. After completion of its function, a block will write a new value to the state register to enable the next block. With several modules writing to the register, usual precautions must be taken to avoid more than one drivers forcing a line simultaneously. All modules must be designed to go to high impedance on their output lines when they are not active.


Miscellaneous non-state-based components

Please refer to the individual design detail pages for:


Interface

Multiplexed Intel Bus and internal I/O timing scheme enforced by FPGA clocks

The compact approach to wire and poll the EC is via the Multiplexed Intel bus format. Aside from some use of the interrupt and reset pins, all communication is done via this bus. (The control architecture of the chip uses 8-bit registers selected with 8-bit addresses.) A communication over this bus begins with an pulse on the "ALE" pin, by the fall of which a valid address is expected on the 8-bit inout "AD" bus. After this /RD (/WR) signal falls, executing the read (write) process, and then rises accompanied with valid input from (to) the chip. The adjacent figure illustrates this process along with the approach to timing the conversation taken in this design. Please refer to Section 16.2 in the manual for details on the timing tolerances on this bus.

As shown in the figure, the 20 MHz clock is very convenient for metering this conversation. The communication delay for the FPGA (most of which runs essentially on 5 MHz) turns out to be only two clock cycles.

This communication standard calls for a bridge module that communicates with the EC upon request from other modules. A "Transceiver" was designed for this purpose. It abstracts the communication with the EC as well as the clock frequency difference. This module in fact subdivides the main 20 MHz; clock to generate the "slow" 5 MHz clock for the rest of the FPGA. Please refer to the detailed page on the Transceiver for more information.


Combined control flow

Operation course between the digital board and the controller PC

Conceptually, the operation course must proceed as outlined in the adjacent figure. The main concern in the tagger control is maintaining a map between board/channel addresses and actual energy bins. For this purpose, the diagrammed two-stage reset plan was devised in the course of which the FPGA learns the PC's MAC address and the PC builds a MAC-Location lookup table. (The "Location" is an 8-byte slot identifier which allows the PC to pinpoint the SiPM channel group.)

The internal FPGA operation course that supports this scheme (and the general control board functionality requirements) is outlined below.

DigBoardScheme.png


Emulator

Since the modules described here represent the core of the FPGA, their combined simulation calls for inclusion of all other fringe modules. Essentially the whole FPGA will have to be tested to ensure this scheme for the core is acting properly. The challenge is in the complexity of the stimulus for such simulation: whole packets will need to be sent in and possibly inter-packet Ethernet Controller Chip states tested.

A stripped down emulator for the Ethernet Controller has been written. It is a essentially a set of registers with a Multiplexed Intel bus communication layer and packet file read/write layers. These registers, however, are not passive memory banks but include "events" that are triggered by particular register states. For instance writing to registers designated to make up a receive buffer pointer actually delivers the requested byte from the buffer to the appropriate control register to be available for a subsequent request. A simple interrupt system (stimulated externally by the simulation layer) has also been included.


See Also