source: firmware/FTM/doc/v4.3/FTM_firmware_specs_v4-3.tex@ 13188

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23
24\title{\vspace*{-7cm} \Huge \bf FTM Firmware Specifications}
25\author{\Large Patrick Vogler\footnote{Contact for questions and suggestions concerning this
26 document: {\tt patrick.vogler@phys.ethz.ch}}, Quirin Weitzel}
27\date{\vspace*{0.5cm} \Large v4.3~~~-~~~May 2011}
28
29\begin{document}
30
31\maketitle
32
33\newpage
34
35\tableofcontents
36
37%---------------------------------------------------------------------------------
38
39\chapter{Introduction}
40\label{cha:Introduction}
41
42The FTM (FACT Trigger Master) board collects the trigger primitives from all
4340 FTU boards (FACT Trigger Unit) and generates the trigger signal for the
44FACT camera. The trigger logic is a 'n-out-of-40' majority coincidence of all
45trigger primitives. Beside the trigger, the FTM board also generates a
46trigger-ID (see chapter \ref{cha:Trigger-ID}). It is controlled from outside
47via ethernet. Two auxiliary RS-485 interfaces are also available.
48
49In addition to the trigger, the FTM board also generates other fast control
50signals: Time-Marker (TIM), DRS \cite{DRS4} reference clock (CLD) and
51reset. These four fast control signals are distributed to the FAD (FACT Analog
52to Digital) boards via two FFC (FACT Fast Control) boards. The FTM board also
53provides via the TIM line the signal for the DRS timing calibration. In order
54to generate the CLD DRS reference clock, as well as the time-marker signal for
55DRS timing calibration, the FTM board uses a clock conditioner
56\cite{LMK03000}.
57
58The FTM board has two time counters, the 'timestamp counter' and the 'on-time
59counter'. While the 'timestamp counter' runs continuously, the 'on-time
60counter' only counts when the camera trigger is enabled.
61
62The FTM board further serves as slow control master for the 40 FTU boards. The
63slow control of the FTU boards and the distribution of the trigger-ID to the
64FAD boards are performed via dedicated RS-485 buses. Because the FAD as well
65as the FTU boards are arranged in crates of 10 boards each, the FTM board has
66four connectors, one for each crate. Running over these connectors there are
67two RS-485 buses (one for FTU slow control and one for the trigger-ID) besides
68the busy signal from the FAD boards and the crate reset.
69
70In addition, the FTM board controls the two FLPs (FACT Light Pulser) via four
71LVDS signals each. Light pulser~1 is located in the mirror dish, light
72pulser~2 inside the camera shutter. There are also digital auxiliary in- and
73outputs according to the NIM (Nuclear Instrumentation Module) standard, for
74example for external triggers and veto, and to have the signals accessible.
75
76The main component of the FTM board is a FPGA (Xilinx Spartan
77XC3SD3400A-4FGG676C), fulfilling the main functions within the board. The
78purpose of this document is to provide specifications needed for the
79development of the firmware of this FPGA and the software (called 'FTMcontrol'
80in the following) controlling the FTM board. For further information about the
81FTM board hardware please refer to \cite{FTM-Schematics}.
82
83\chapter{Trigger-ID}
84\label{cha:Trigger-ID}
85
86For each processed trigger the FTM board generates a unique trigger-ID to be
87broadcasted to all FAD boards and added to the event data. This trigger-ID
88consists of a 32 bit trigger number, a two byte trigger type indicator and a
89checksum. The transmission protocol for the trigger-ID broadcast is shown in
90table \ref{tab:Trigger-ID broadcast}.
91
92\begin{table}[htbp]
93\centering
94\begin{tabular}{|l|l|}\hline
95byte no & content\\\hline\hline
960 & Trigger-No first byte (least significant byte) \\\hline
971 & Trigger-No second byte\\\hline
982 & Trigger-No third byte\\\hline
993 & Trigger-No forth byte (most significant byte)\\\hline
1004 & Trigger-Type 1\\\hline
1015 & Trigger-Type 2\\\hline
1026 & CRC-8-CCITT (checksum)\\\hline
103\end{tabular}
104\caption{The transmission protocol to broadcast the trigger-ID to the FAD boards}
105\label{tab:Trigger-ID broadcast}
106\end{table}
107
108A Cyclic Redundancy Check (CRC) over byte 0 - 5 is used to evaluate the
109integrity of the trigger-ID. An 8-CCITT CRC has been chosen which is based on
110the polynomial $x^8 + x^2 + x + 1$ (00000111, omitting the most significant
111bit). The resulting 1-byte checksum comprises the last byte of the trigger-ID.
112The transmission of the trigger-ID to the FAD boards is done by means of
113dedicated RS-485 buses (one per crate).
114
115In the first byte of the trigger type indicator (see table
116\ref{tab:Trigger-Type 1}) n0 - n5 indicate the number of trigger primitives
117required for a trigger, thus the 'n' of the 'n-out-of-40' majority
118coincidence. The two flags 'external trigger 1' and 'external trigger 2',
119when set, indicate a trigger from the corresponding NIM inputs. See also
120section \ref{sec:Static-data-block} and table \ref{tab:FTM-majority} for
121further information.
122
123\begin{table}[htbp]
124\centering
125%\begin{small}
126\begin{tabular}{|l|l|l|l|l|l|l|l|}\hline
127 Bit7 & Bit6 & Bit5 & Bit4 & Bit3 & Bit2 & Bit1 & Bit0\\\hline\hline
128 n5 & n4 & n3 & n2 & n1 & n0 & external trigger 2 & external trigger 1\\\hline
129\end{tabular}
130%\end{small}
131\caption{Trigger-Type 1}
132\label{tab:Trigger-Type 1}
133\end{table}
134
135\begin{table}[htbp]
136\centering
137\begin{small}
138\begin{tabular}{|l|l|l|l|l|l|l|l|}\hline
139Bit7 & Bit6 & Bit5 & Bit4 & Bit3 & Bit2 & Bit1 & Bit0\\\hline\hline
140TIM source & LP\_set\_3 & LP\_set\_2 & LP\_set\_1 & LP\_set\_0 & pedestal & LP\_2 & LP\_1\\\hline
141\end{tabular}
142\end{small}
143\caption{Trigger-Type 2}
144\label{tab:Trigger-Type 2}
145\end{table}
146
147The 'TIM source' bit in 'Trigger-Type 2' (see table \ref{tab:Trigger-Type 2})
148indicates the source of the timemarker signal: a '0' indicates the timemarker
149being produced in the FPGA while a '1' indicates the timemarker coming from
150the clock conditioner. The flags 'LP\_1' and 'LP\_2' are set when the
151corresponding lightpulser has flashed while the 'pedestal' flag is set in case
152of a pedestal (random) trigger. An event having none of these flags set
153indicates a physics event. The bits 'LP\_set\_0' to 'LP\_set\_3' are used to
154code information about the light pulser settings. They only have a meaning in
155case of calibration events.
156
157\chapter{FTM Commands}
158\label{cha:FTM-Commands}
159
160The communication between the FTM board and the FTMcontrol software, including
161the corresponding commands, protocols and data, is based on 16-bit words and
162big-endian. This is to facilitate the data-transmission over the Wiznet W5300
163ethernet interface \cite{W5300}.
164
165The basic structure of all commands is the same and given in table
166\ref{tab:FTM-command-structure}. After a start delimiter, the second word
167identifies the command. Next there is a parameter further refining the
168command, e.g. what to read. The fourth and fifth words are spares and should
169contain zeros. Starting from the sixth word, an optional data block of
170variable size is following. This data block differs in length and content
171depending on command and parameter. In case of 'read' instructions, the
172corresponding data block is sent back.
173
174%The FTM board must answer every command by sending back the appropriate data
175%block or by simply sending back the instruction where there is no datablock to
176%be sent back. All 'read' commands to the FTM board do not contain any data
177%blocks, but the FTM boards response does. In case of 'read' and 'write'
178%instructions, the datablock is to be sent back. When 'start run' or 'stop run'
179%commands are used, the FTM board 'mirrors' them, i.e. sends them back for
180%confirmation.
181
182\begin{table}[p]
183\centering
184\begin{tabular}{|l|l|}\hline
185 word no & content\\\hline\hline
186 0 & start delimiter (e.g. '@') \\\hline
187 1 & command ID \\\hline
188 2 & command parameter \\\hline
189 3 & spare: containing 0x0000\\\hline
190 4 & spare: containing 0x0000 \\\hline
191 5 & data block (optional and of variable size)\\\hline
192 ... & ...\\\hline
193 X & data block\\\hline
194\end{tabular}
195\caption{FTM command structure}
196\label{tab:FTM-command-structure}
197\end{table}
198
199So far seven different commands are foreseen: 'read', 'write', 'start run',
200'stop run', 'ping FTUs', 'crate reset' and 'autosend on/off' (see table
201\ref{tab:FTM-command-ID}). The command parameters of the 'read' and write
202commands are shown in table~\ref{tab:FTM-read-command-param} and
203table~\ref{tab:FTM-write-command-param}, respectively. With the 'autosend
204on/off' command it is possible to switch off the automatic sending of trigger
205rates and error messages (see table~\ref{tab:FTM-as-command-param}).
206
207\begin{table}[p]
208\centering
209\begin{tabular}{|r|r|}\hline
210 command-ID: bits & \\\cline{1-1}
211 15 ... 8 \vline 7 \vline 6 \vline 5 \vline 4 \vline 3 \vline 2 \vline 1 \vline 0 & command\\\hline\hline
212 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 & read \\\hline
213 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 & write \\\hline
214 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 \vline 0 & start run / take X events\\\hline
215 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 \vline 0 \vline 0 & stop run \\\hline
216 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 \vline 0 \vline 0 \vline 0 & ping all FTUs \\\hline
217 0 \vline 0 \vline 0 \vline 1 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 & crate reset \\\hline
218 0 \vline 0 \vline 1 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 & autosend on/off \\\hline
219\end{tabular}
220\caption{FTM command ID listing}
221\label{tab:FTM-command-ID}
222\end{table}
223
224\begin{table}[p]
225\centering
226\begin{tabular}{|r|r|r|}\hline
227 command parameter: bits & & \\\cline{1-1}
228 15 ... 8 \vline 7 \vline 6 \vline 5 \vline 4 \vline 3 \vline 2 \vline 1 \vline 0 & command & data block\\\hline\hline
229 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 & read complete static data block & no\\\hline
230 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 & read complete dynamic data block & no\\\hline
231 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 \vline 0 &
232 read single address of static data block & address\\\hline
233 %0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 \vline 0 & read trigger list & no\\\hline
234\end{tabular}
235\caption{Command parameters for the 'read' command; only for the static data
236 block single addresses can be read.}
237\label{tab:FTM-read-command-param}
238\end{table}
239
240\begin{table}[p]
241\centering
242\begin{tabular}{|r|r|r|}\hline
243 command parameter: bits & & \\\cline{1-1}
244 15 ... 8 \vline 7 \vline 6 \vline 5 \vline 4 \vline 3 \vline 2 \vline 1 \vline 0 & command & data block\\\hline\hline
245 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 & write complete static data block & all configuration data\\\hline
246 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 \vline 0 &
247 write single address of static data block & address + data\\\hline
248\end{tabular}
249\caption{Command parameters for the 'write' command; only the static data
250 block can be written, therefore parameter value 0x2 is not used.}
251\label{tab:FTM-write-command-param}
252\end{table}
253
254\begin{table}[p]
255\centering
256\begin{tabular}{|r|r|r|}\hline
257 command parameter: bits & & \\\cline{1-1}
258 15 ... 8 \vline 7 \vline 6 \vline 5 \vline 4 \vline 3 \vline 2 \vline 1 \vline 0 & command & data block\\\hline\hline
259 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 & reports disabled & no\\\hline
260 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 & reports enabled & no\\\hline
261\end{tabular}
262\caption{Command parameters for the 'autosend on/off' command}
263\label{tab:FTM-as-command-param}
264\end{table}
265
266%\begin{table}[htbp]
267%\centering
268%\begin{tabular}{|r|r|r|}\hline
269% command parameter: bits & & \\\cline{1-1}
270% 15 ... 8 \vline 7 \vline 6 \vline 5 \vline 4 \vline 3 \vline 2 \vline 1 \vline 0 & command & data block\\\hline\hline
271% 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline0 \vline 0 \vline0 \vline1 & write static data & static data block\\\hline
272%\end{tabular}
273%\caption{Command parameters for the 'write' command}
274%\label{tab:FTM-write-command-param}
275%\end{table}
276
277In table \ref{tab:FTM-start-command-param} the parameters to start a run are
278listed. The type of the run is fully described in the FTM configuration
279(static data block, see section~\ref{sec:Static-data-block}), which always has
280to be sent by the FTMcontrol before starting a run. Therefore the only
281option is to start an "endless" run or to take X events instead. In the latter
282case X is defined by a two words (32 bit) long unsigned integer, making up the
283command data block. The 'start run' command enables the transmission of
284trigger signals (physics, calibration or pedestal) to the FAD boards and
285resets the trigger and time counters. There is no parameter for stopping a
286run. If a number of events has been specified ('take X events'), the run will
287terminate if either the 'stop run' command is received or the requested number
288of events is reached. In any case the trigger and time counters are reset,
289too.
290
291\begin{table}[p]
292\centering
293\begin{tabular}{|r|r|r|}\hline
294 command parameter: bits & & \\\cline{1-1}
295 15 ... 8 \vline7 \vline 6 \vline 5 \vline 4 \vline 3 \vline 2 \vline 1 \vline 0 & command & data block\\\hline\hline
296 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 & start run & no \\\hline
297 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 & take X events & number of events X \\\hline
298 %0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 \vline 0 & start taking pedestals & no \\\hline
299 %0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 \vline 1 & take X pedestals events & number of events X \\\hline
300 %0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 \vline 0 \vline 0 & start calibration run & no \\\hline
301 %0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 \vline 0 \vline 1 & take X calibration events & number of events X \\\hline
302\end{tabular}
303\caption{Command parameters for the 'start run' command: "start run" means an
304 "endless" run, i.e. no pre-defined number of events; if a number of events X
305 is specified, this is done with a 32-bit unsigned long integer (big endian).}
306\label{tab:FTM-start-command-param}
307\end{table}
308
309%\begin{table}[htbp]
310%\centering
311%\begin{tabular}{|r|r|r|}\hline
312% command parameter: bits & & \\\cline{1-1}
313% 15 ... 8 \vline 7 \vline 6 \vline 5 \vline 4 \vline 3 \vline 2 \vline 1 \vline 0 & command & data block\\\hline\hline
314% 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 & stop run & no\\\hline
315%\end{tabular}
316%\caption{Command parameter for the 'stop run' command}
317%\label{tab:FTM-stop-command-param}
318%\end{table}
319
320In case of a 'ping FTUs' command the FTM will address the FTUs one by one and
321readout their DNA. The results are collected in the FTU list (see section
322\ref{sec:FTU-List}), which is sent back to the FTMcontrol. There are no
323parameters for this command. With the 'crate reset' command the boards of a
324particular crate can be rebooted, where the command parameter defines the
325crate number (see table \ref{tab:FTM-reset-command-param}). Only one crate
326reset at a time is possible, i.e. the FTM firmware does not allow to reset
327multiple crates in one command.
328
329\begin{table}[p]
330\centering
331\begin{tabular}{|r|r|r|}\hline
332 command parameter: bits & & \\\cline{1-1}
333 15 ... 8 \vline 7 \vline 6 \vline 5 \vline 4 \vline 3 \vline 2 \vline 1 \vline 0 & command & data block\\\hline\hline
334 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 & reset crate 0 & no\\\hline
335 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 & reset crate 1 & no\\\hline
336 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 \vline 0 & reset crate 2 & no\\\hline
337 0 \vline 0 \vline 0 \vline 0 \vline 0 \vline 1 \vline 0 \vline 0 \vline 0 & reset crate 3 & no\\\hline
338\end{tabular}
339\caption{Command parameters for the 'crate reset' command: the command parameter may only contain a single "1"
340 corresponding to only one crate reset at a time.}
341\label{tab:FTM-reset-command-param}
342\end{table}
343
344\chapter{FTM data blocks}
345\label{cha:FTM-data-block}
346
347The trigger master features two main data blocks, named 'static data block'
348and 'dynamic data block' in the following. They are implemented in the
349firmware as block-RAM. In addition, there is the so-called 'FTU list', which
350is filled only on request ('ping FTUs' command). If any of these blocks is
351sent to the FTMcontrol (either automatically or on demand), a header with a
352size of 14 words is added, and the whole data package is put between a start
353and an end delimiter (see table~\ref{tab:FTM-package}). The header is
354identical for all data blocks and contains solely read-only information: the
355type and length of the package, the FTM status, the FTM board ID (57-bit
356Xilinx device DNA \cite{ds557, ds610, wp267, wp266}), a firmware ID and the
357readings of the trigger counter and time stamp counter (see
358table~\ref{tab:FTM-header}).
359
360\begin{table}[h]
361\centering
362\begin{tabular}{|c|c|c|c|}\hline
363 start delimiter & header & data block & end delimiter \\\hline
364 0xFB01 & 14 words & optional size & 0x04FE\\\hline
365\end{tabular}
366\caption{Structure of a data package as sent by the FTM to the FTMcontrol
367 software. The start and end delimiters are the same as used for the FAD boards.}
368\label{tab:FTM-package}
369\end{table}
370
371\begin{table}[h]
372\centering
373\begin{tabular}{|l|l|c|}\hline
374 word no & content & description\\\hline\hline
375 0x000 & type of data package & 1: SD, 2: DD, 3: FTU-list, 4: error, 5: single SD-word\\\hline
376 0x001 & length of data package & after header, including end delimiter\\\hline
377 0x002 & status of FTM & 1: IDLE, 2: CONFIG, 3: RUNNING, 4: CALIB\\\hline
378 0x003 & board ID bits 63...48 & FPGA device DNA\\\hline
379 0x004 & board ID bits 47...32 & FPGA device DNA\\\hline
380 0x005 & board ID bits 31...16 & FPGA device DNA\\\hline
381 0x006 & board ID bits 15... 0 & FPGA device DNA\\\hline
382 0x007 & firmware ID & defined as a VHDL constant\\\hline
383 0x008 & trigger counter bits 31...16 & at read-out time\\\hline
384 0x009 & trigger counter bits 15... 0 & at read-out time\\\hline
385 0x00A & time stamp bits 63...48 & filled up with zeros\\\hline
386 0x00B & time stamp bits 47...32 & at read-out time\\\hline
387 0x00C & time stamp bits 31...16 & at read-out time\\\hline
388 0x00D & time stamp bits 15... 0 & at read-out time\\\hline
389\end{tabular}
390\caption{Header structure for sending a data block or error message}
391\label{tab:FTM-header}
392\end{table}
393
394\section{Static data block}
395\label{sec:Static-data-block}
396
397The static data block contains all the settings needed to configure and
398operate the FTM. It has to be written by the FTMcontrol each time before a run
399is started or, in general, some component has to be reprogrammed. Single
400register access is possible, but not foreseen for the standard data taking. In
401addition, whenever the FTM board receives a new static data block, it performs
402a complete reconfiguration including a reprogramming of the
403FTUs. Table~\ref{tab:FTM-trigger-master-static-data-block} summarizes the
404static data block. More details about the individual registers can be found in
405the subsequent tables.
406
407%These settings are readable and writable by the main control using the
408%corresponding commands 'read static data block' or 'write static data block',
409%respectively. There is one exception from writability: In case the static
410%data block is read back, the first eleven words (address 0..A) are identical
411%with the dynamic data block and the trigger list shown in
412%\ref{tab:FTM-trigger-master-dynamic-data-block} and
413%\ref{tab:FTM-trigger-list}. These first eleven words can only be read and not
414%written. The board ID is supposed to be the Xilinx device DNA \cite{ds557,
415% ds610, wp267, wp266}, the 57 bit device ID of the FPGA. When using the
416%'write static data block' command, the static data block must start with the
417%'general settings register' at address 0x00B. So there is an offset in the
418%addresses of 0x00B between the 'read-out-version' and the 'write-version' of
419%the static data block.
420
421\begin{longtable}[h]{|l|l|c|}\hline
422\centering
423word no & content & description\\\hline\hline
4240x000 & general settings & see table~\ref{tab:FTM-general-settings-register} and text\\\hline
4250x001 & on-board status LEDs & see table~\ref{tab:FTM-LED-register}\\\hline
4260x002 & light pulser and pedestal trigger period & see table~\ref{tab:FTM-frequency-register} and text\\\hline
4270x003 & sequence of LP1, LP2 and PED triggers & see table~\ref{tab:FTM-ratio-register} and text\\\hline
428
4290x004 & light pulser 1 amplitude & see table~\ref{tab:LP1-amplitude-register} and text\\\hline
4300x005 & light pulser 2 amplitude & see table~\ref{tab:LP2-amplitude-register} and text\\\hline
4310x006 & light pulser 1 delay & 8ns + delay value*4ns\\\hline
4320x007 & light pulser 2 delay & 8ns + delay value*4ns\\\hline
433
4340x008 & majority coincidence n (for physics) & see table~\ref{tab:FTM-majority} and text\\\hline
4350x009 & majority coincidence n (for calibration) & see table~\ref{tab:FTM-majority} and text\\\hline
4360x00A & trigger delay & 8ns + delay value*4ns, 10 bits used\\\hline
4370x00B & timemarker delay & 8ns + delay value*4ns, 10 bits used\\\hline
4380x00C & dead time & 8ns + value*4ns, 16 bits used\\\hline
4390x00D & clock conditioner R0 bits 31...16 & \\\hline
4400x00E & clock conditioner R0 bits 15...0 & \\\hline
4410x00F & clock conditioner R1 bits 31...16 & \\\hline
4420x010 & clock conditioner R1 bits 15...0 & \\\hline
4430x011 & clock conditioner R8 bits 31...16 & \\\hline
4440x012 & clock conditioner R8 bits 15...0 & \\\hline
4450x013 & clock conditioner R9 bits 31...16 & \\\hline
4460x014 & clock conditioner R9 bits 15...0 & \\\hline
4470x015 & clock conditioner R11 bits 31...16 & \\\hline
4480x016 & clock conditioner R11 bits 15...0 & \\\hline
4490x017 & clock conditioner R13 bits 31...16 & \\\hline
4500x018 & clock conditioner R13 bits 15...0 & \\\hline
4510x019 & clock conditioner R14 bits 31...16 & \\\hline
4520x01A & clock conditioner R14 bits 15...0 & \\\hline
4530x01B & clock conditioner R15 bits 31...16 & \\\hline
4540x01C & clock conditioner R15 bits 15...0 & \\\hline
4550x01D & maj. coinc. window (for physics) & 8ns + value*4ns, 4 bits used\\\hline
4560x01E & maj. coinc. window (for calibration) & 8ns + value*4ns, 4 bits used \\\hline
4570x01F & spare & \\\hline
4580x020 & enables patch 0 board 0 crate 0 & see FTU documentation\\\hline
4590x021 & enables patch 1 board 0 crate 0 & see FTU documentation\\\hline
4600x022 & enables patch 2 board 0 crate 0 & see FTU documentation\\\hline
4610x023 & enables patch 3 board 0 crate 0 & see FTU documentation\\\hline
4620x024 & DAC$\_$A board 0 crate 0 & see FTU documentation \\\hline
4630x025 & DAC$\_$B board 0 crate 0 & see FTU documentation \\\hline
4640x026 & DAC$\_$C board 0 crate 0 & see FTU documentation \\\hline
4650x027 & DAC$\_$D board 0 crate 0 & see FTU documentation \\\hline
4660x028 & DAC$\_$H board 0 crate 0 & see FTU documentation \\\hline
4670x029 & Prescaling board 0 crate 0 & (value+1)/2~[s], also autosend period \\\hline
4680x02A & enables patch 0 board 1 crate 0 & see FTU documentation \\\hline
4690x02B & enables patch 1 board 1 crate 0 & see FTU documentation \\\hline
4700x02C & enables patch 2 board 1 crate 0 & see FTU documentation \\\hline
4710x02D & enables patch 3 board 1 crate 0 & see FTU documentation \\\hline
4720x02E & DAC$\_$A board 1 crate 0 & see FTU documentation \\\hline
4730x02F & DAC$\_$B board 1 crate 0 & see FTU documentation \\\hline
4740x030 & DAC$\_$C board 1 crate 0 & see FTU documentation \\\hline
4750x031 & DAC$\_$D board 1 crate 0 & see FTU documentation \\\hline
4760x032 & DAC$\_$H board 1 crate 0 & see FTU documentation \\\hline
4770x033 & Prescaling board 1 crate 0 & see FTU documentation \\\hline
478... & ... & \\\hline
4790x1A6 & enables patch 0 board 9 crate 3 & see FTU documentation \\\hline
4800x1A7 & enables patch 1 board 9 crate 3 & see FTU documentation \\\hline
4810x1A8 & enables patch 2 board 9 crate 3 & see FTU documentation \\\hline
4820x1A9 & enables patch 3 board 9 crate 3 & see FTU documentation \\\hline
4830x1AA & DAC$\_$A board 9 crate 3 & see FTU documentation \\\hline
4840x1AB & DAC$\_$B board 9 crate 3 & see FTU documentation \\\hline
4850x1AC & DAC$\_$C board 9 crate 3 & see FTU documentation \\\hline
4860x1AD & DAC$\_$D board 9 crate 3 & see FTU documentation \\\hline
4870x1AE & DAC$\_$H board 9 crate 3 & see FTU documentation \\\hline
4880x1AF & Prescaling board 9 crate 3 & see FTU documentation \\\hline
4890x1B0 & active FTU list crate 0 & see FTU documentation \\\hline
4900x1B1 & active FTU list crate 1 & see FTU documentation \\\hline
4910x1B2 & active FTU list crate 2 & see FTU documentation \\\hline
4920x1B3 & active FTU list crate 3 & see FTU documentation \\\hline
493\caption{Overview of the FTM static data block}
494\label{tab:FTM-trigger-master-static-data-block}
495\end{longtable}
496
497The FTM general settings register is detailed in table
498\ref{tab:FTM-general-settings-register}. The 'TIM\_CLK' bit defines whether
499the time marker is generated by the FPGA ('TIM\_CLK' = 0, default for physics
500data taking), or whether it is generated by the clock conditioner ('TIM\_CLK'
501= 1, e.g. for DRS timing calibration). The 'ext\_veto', 'ext\_trig\_1' and
502'ext\_trig\_2' bits enable (1) or disable (0) the NIM inputs for the external
503veto and trigger signals, respectively. In order to select which trigger
504sources are active during a run, the bits 'LP1', 'LP2', 'ped' and 'trigger'
505are foreseen (0 disabled, 1 enabled). During a physics run, for example,
506'LP1', 'ped' and 'trigger' should all be set to generate interleaved
507calibration and pedestal events as well as activate the 'n-out-of-40' trigger
508input. For a didicated pedestal run only 'ped' should be set, since in this
509case the FTM sends directly a trigger to the FADs. For calibration runs it
510depends on whether the external (LP1) or internal (LP2) light pulser is used:
511For the first case 'LP1' and 'trigger' have to be set, since here the full
512trigger chain is involved and the camera triggers based on G-APD signals. For
513the second case only 'LP2' is needed, because the shutter is closed and the
514FTM sends directly the trigger signal to the FADs (like for pedestal
515events). Bits 8 to 15 of the general settings register are not used up to now.
516
517\begin{table}[h]
518\centering
519\begin{small}
520\begin{tabular}{|l|l|l|l|l|l|l|l|l|l|}\hline
521Bit & 15...8 & 7 & 6 & 5 & 4 & 3 & 2 & 1 & 0 \\\hline
522Content & x & trigger & ped & LP2 & LP1 & ext\_trig\_2 & ext\_trig\_1& ext\_veto & TIM\_CLK \\\hline
523\end{tabular}
524\end{small}
525\caption{FTM general settings register}
526\label{tab:FTM-general-settings-register}
527\end{table}
528
529%\begin{table}[!h]
530%\centering
531%\begin{tabular}{|l|l|}\hline
532%TIM\_CClk & description \\\hline\hline
533%0 & Time marker generated in the FPGA \\\hline
534%1 & Time marker generated by the clock conditioner \\\hline
535%\end{tabular}
536%\caption{FTM Time marker indication}
537%\label{tab:FTM-Time-marker-indication}
538%\end{table}
539
540%\begin{table}[!h]
541%\centering
542%\begin{tabular}{|l|l|}\hline
543%ena$\_$ext$\_$Veto & description \\\hline\hline
544%0 & disable external trigger veto\\\hline
545%1 & enable external trigger veto \\\hline
546%\end{tabular}
547%\caption{FTM external trigger}
548%\label{tab:FTM-external-trigger}
549%\end{table}
550
551%\begin{table}[!h]
552%\centering
553%\begin{tabular}{|l||l|}\hline
554%ena\_LP1 & description \\\hline\hline
555%0 & disable light pulser 1 \\\hline
556%1 & enable light pulser 1\\\hline
557%\end{tabular}
558%\caption{FTM light pulser 1}
559%\label{tab:FTM-light-pulser-1}
560%\end{table}
561
562%\begin{table}[!h]
563%\centering
564%\begin{tabular}{|l||l|}\hline
565%ena\_LP2 & description \\\hline\hline
566%0 & disable light pulser 2 \\\hline
567%1 & enable light pulser 2 \\\hline
568%\end{tabular}
569%\caption{FTM light pulser 2}
570%\label{tab:FTM-light-pulser-2}
571%\end{table}
572
573%\begin{table}[!h]
574%\centering
575%\begin{tabular}{|l||l|}\hline
576%ena\_Ped & description \\\hline\hline
577%0 & disable interleaved pedestal trigger \\\hline
578%1 & enable interleaved pedestal trigger \\\hline
579%\end{tabular}
580%\caption{FTM interleaved pedestals}
581%\label{tab:FTM-interleaved-pedestals}
582%\end{table}
583
584%\begin{table}[!h]
585%\centering
586%\begin{small}
587%\begin{tabular}{|l||l|}\hline
588%ena\_LLC & description \\\hline\hline
589%0 & disable low level calibration pulses \\\hline
590%1 & enable low level calibration pulses \\\hline
591%\end{tabular}
592%\end{small}
593%\caption{FTM low level calibration pulses}
594%\label{tab:FTM-low-level-calibration-pulses}
595%\end{table}
596
597The 'on-board status LEDs' register shown in table \ref{tab:FTM-LED-register}
598allows to switch a total of eight LEDs on the FTM board for debugging purposes
599by setting the corresponding bit high.
600
601\begin{table}[h]
602\centering
603\begin{small}
604\begin{tabular}{|l|l|l|l|l|l|l|l|l|l|}\hline
605Bit & 15...8 & 7 & 6 & 5 & 4 & 3 & 2 & 1 & 0 \\\hline
606Content & x & red$\_$3 & red$\_$2 & gn$\_$1 & ye$\_$1 & red$\_$1 & gn$\_$0 & ye$\_$0 & red$\_$0 \\\hline
607\end{tabular}
608\end{small}
609\caption{'on-board status LEDs' register}
610\label{tab:FTM-LED-register}
611\end{table}
612
613The period (time distance, see table \ref{tab:FTM-frequency-register}), with
614which light pulser and pedestal triggers are sent, is stored in the register
615at address 0x002. It is given in [ms] and adjustable between 1\,ms and
6161023\,ms (10 bits used). The next register defines the sequence of LP1, LP2
617and pedestal events (see table \ref{tab:FTM-ratio-register}).
618
619\begin{table}[h]
620\centering
621\begin{small}
622\begin{tabular}{|l|l|l|l|l|l|l|l|}\hline
623Bit & 15 - 10 & 9 & 8 & ... & 2 & 1 & 0 \\\hline
624Content & x & PERIOD\_9 & PERIOD\_8 & ... & PERIOD\_2 & PERIOD\_1 & PERIOD\_0 \\\hline
625\end{tabular}
626\end{small}
627\caption{Register for the period [ms] of calibration and pedestal events}
628\label{tab:FTM-frequency-register}
629\end{table}
630
631\begin{table}[h]
632\centering
633\begin{small}
634\begin{tabular}{|l|l|l|l|l|l|l|l|l|l|l|}\hline
635Bit & 15 & 14 & ... & 10 & 9 & ... & 5 & 4 & ... & 0 \\\hline
636Content & x & ped\_S4 & ... & ped\_S0 & LP2\_S4 & ... & LP2\_S0 & LP1\_S4 & ... & LP1\_S0 \\\hline
637\end{tabular}
638\end{small}
639\caption{Register defining the sequence of LP1, LP2 and pedestal events; 5
640 bits used per value. By setting e.g. LP1/LP2/PED = 3/2/1, the systems
641 generates 3 LP1 triggers, followed by 2 LP2 triggers, followed by 1 PED
642 trigger (if they are also activated in the 'general settings' register).
643 The distance between the triggers is defined with another register
644 (table~\ref{tab:FTM-frequency-register}).}
645\label{tab:FTM-ratio-register}
646\end{table}
647
648%\begin{table}[!h]
649%\centering
650%\begin{tiny}
651%\begin{tabular}{|l|l|l|l|l|l|l|l|l|l|l|l|l|l|l|l|l|}\hline
652%Bit & 15 - 10 & 9 & 8 & 7 & 6 & 5 & 4 & 3 & 2 & 1 & 0 \\\hline
653%Function & x & LPR2\_9 & LPR2\_8 & LPR2\_7 & LPR2\_6 & LPR2\_5 & LPR2\_4 & LPR2\_3 & LPR2\_2 & LPR2\_1 & LPR2\_0 \\\hline
654%\end{tabular}
655%\end{tiny}
656%\caption{Light pulser 2 frequency register at address 0x00E: This register contains the pulse rate of the light
657% pulser 2 in Hz.}
658%\label{tab:Light-pulser-2-frequancy-register}
659%\end{table}
660
661
662
663
664
665
666
667
668
669
670
671In order to define the amplitude and characteristics of the light pulses that
672are generated by the LP1 and the LP2 system, the registers 'LP1 amplitude' and
673'LP2 amplitude' are used, respectively. These registers are presented in
674table~\ref{tab:LP1-amplitude-register} and table~\ref{tab:LP2-amplitude-register}.
675The two most significant bit allow to switch on additional LEDs, while the six
676least significant bits are used for the FM (frequency modulation) on the
677light pulser board. These six bits (FM1\_5 ... FM1\_0 and FM2\_5 ... FM2\_0
678respectively) are frequency dividing factors and the resulting frequency for the
679feedback is $ f_{FM} = \frac{5MHz}{25 + \mid FM1\_5 ... FM1\_0 \mid} $.
680
681
682
683
684This FM signal is used for stabilizing the amplitude
685of the light pulses, see the schematics \cite{FLD-Schematics}.
686
687The light pulser systems are controlled from the FTM by means of four LVDS control lines:
688The first line goes directly to the LED driver circuit and triggers a lightpulse.
689The FM signal is on the second line.
690The third and forth line allow to switch on additional LEDs.
691
692
693
694
695
696
697
698
699\begin{table}[!h]
700\centering
701\begin{small}
702\begin{tabular}{|l|l|l|l|l|}\hline
703Bit & 15 & 14 & 13 ... 6 & 5 ... 0 \\\hline
704Content & add\_LEDs1\_1& add\_LEDs1\_0 & x & FM1\_5 ... FM1\_0 \\\hline
705\end{tabular}
706\end{small}
707\caption{Light pulser 1 amplitude register}
708\label{tab:LP1-amplitude-register}
709\end{table}
710
711
712
713
714\begin{table}[!h]
715\centering
716\begin{small}
717\begin{tabular}{|l|l|l|l|l|}\hline
718Bit & 15 & 14 & 13 ... 6 & 5 ... 0 \\\hline
719Content & add\_LEDs2\_1& add\_LEDs2\_0 & x & FM2\_5 ... FM2\_0 \\\hline
720\end{tabular}
721\end{small}
722\caption{Light pulser 2 amplitude register}
723\label{tab:LP2-amplitude-register}
724\end{table}
725
726
727
728
729
730
731
732
733
734
735
736
737
738
739
740
741
742The different settings of the 'n-out-of-40' logic (physics or calibration
743events) are stored in two separate registers, which both have a structure
744according to table~\ref{tab:FTM-majority}.
745
746\begin{table}[!h]
747\centering
748\begin{small}
749\begin{tabular}{|l|l|l|l|l|l|l|l|}\hline
750Bit & 15...6 & 5 & 4 & 3 & 2 &1 & 0 \\\hline
751Content & x & n5 & n4 & n3 & n2 & n1 & n0 \\\hline
752\end{tabular}
753\end{small}
754\caption{Structure of the two majority coincidence (n-out-of-40) registers; the binary value
755 in these registers is the minimum number n of FTU trigger primitives required to trigger an event (physics or calibration)}
756\label{tab:FTM-majority}
757\end{table}
758
759In addition, there are several registers in the static data block to define
760delays (e.g. for the trigger). Also a general dead time to be applied after
761each trigger can be set (to compensate for the delay of the busy line). The
762clock conditioner settings are specified at address 0x00D to 0x01C (LMK03000
763from National Semiconductor, for more details see \cite{LMK03000}).
764
765Starting at address 0x020, the FTU settings are stored. The FTM always holds
766the complete FTU parameters in the static data block. For the meaning of these
767registers, please refer to the FTU firmware specifications document
768\cite{FTUspecs}. The register at address 0x029 is special in the sense that,
769in addition to its normal meaning, it also defines the time period with which
770the FTU rates are sent automatically to the FTMcontrol software. In case not
771all FTUs are connected during e.g. the testing phase, or a FTU is broken, the
772'active FTU list' registers can be used to disable certain boards. Bits 9...0
773of one of the active FTU lists (address 0x1B0 to 0x1B3, corresponding to crate
7740 to 3) contain the "active" flag for every FTU board. Setting a bit activates
775the corresponding FTU board while a "0" deactivates it.
776
777\section{Dynamic data block}
778\label{sec:Dynamic-data-block}
779The dynamic data block shown in table \ref{tab:FTM-dynamic-data-block}
780contains permanently updated data stored inside the FTM FPGA. It contains the
781actual on-time counter reading, the board temperatures and the trigger rates
782measured by the FTUs. This data block is updated and sent periodically by the
783FTM. Thus the FTMcontrol software receives periodically a corresponding data
784package via ethernet. The counting interval of the FTU board 0 on crate 0
785('prescaling' register) defines the period. The on-board 12-bit temperature
786sensors are MAX6662 chips from Maxim Products. For more information about
787these components and their data see \cite{MAX6662}. When sending the dynamic
788data block, the header defined in table~\ref{tab:FTM-header} is added at the
789beginning.
790
791\newpage
792
793% \begin{table}[h]
794% \centering
795\begin{longtable}[h]{|l|l|}\hline
796word no & content\\\hline\hline
7970x000 & on-time counter at read-out time bits 63...48, filled up with zeros \\\hline
7980x001 & on-time counter at read-out time bits 47...32 \\\hline
7990x002 & on-time counter at read-out time bits 31...16 \\\hline
8000x003 & on-time counter at read-out time bits 15...0 \\\hline
8010x004 & temperature sensor 0: component U45 on the FTM schematics \cite{FTM-Schematics}\\\hline
8020x005 & temperature sensor 1: U46 \\\hline
8030x006 & temperature sensor 2: U48 \\\hline
8040x007 & temperature sensor 3: U49 \\\hline
8050x008 & rate counter bit 29...16 patch 0 board 0 crate 0 \\\hline
8060x009 & rate counter bit 15...0 patch 0 board 0 crate 0 \\\hline
8070x00A & rate counter bit 29...16 patch 1 board 0 crate 0 \\\hline
8080x00B & rate counter bit 15...0 patch 1 board 0 crate 0 \\\hline
8090x00C & rate counter bit 29...16 patch 2 board 0 crate 0 \\\hline
8100x00D & rate counter bit 15...0 patch 2 board 0 crate 0 \\\hline
8110x00E & rate counter bit 29...16 patch 3 board 0 crate 0 \\\hline
8120x00F & rate counter bit 15...0 patch 3 board 0 crate 0 \\\hline
8130x010 & rate counter bit 29...16 total board 0 crate 0 \\\hline
8140x011 & rate counter bit 15...0 total board 0 crate 0\\\hline
8150x012 & Overflow register board 0 crate 0 \\\hline
8160x013 & CRC-error register board 0 crate 0 \\\hline
8170x014 & rate counter bit 29...16 patch 0 board 1 crate 0 \\\hline
8180x015 & rate counter bit 15...0 patch 0 board 1 crate 0 \\\hline
8190x016 & rate counter bit 29...16 patch 1 board 1 crate 0 \\\hline
8200x017 & rate counter bit 15...0 patch 1 board 1 crate 0 \\\hline
8210x018 & rate counter bit 29...16 patch 2 board 1 crate 0 \\\hline
8220x019 & rate counter bit 15...0 patch 2 board 1 crate 0 \\\hline
8230x01A & rate counter bit 29...16 patch 3 board 1 crate 0 \\\hline
8240x01B & rate counter bit 15...0 patch 3 board 1 crate 0 \\\hline
8250x01C & rate counter bit 29...16 total board 1 crate 0 \\\hline
8260x01D & rate counter bit 15...0 total board 1 crate 0 \\\hline
8270x01E & Overflow register board 1 crate 0 \\\hline
8280x01F & CRC-error register board 1 crate 0 \\\hline
829... & ... \\\hline
8300x1E7 & CRC-error register board 9 crate 3 \\\hline
831% \end{longtable}
832\caption{FTM dynamic data block}
833\label{tab:FTM-dynamic-data-block}
834\end{longtable}
835
836%\section{Trigger-list}
837%\label{sec:trigger-list}
838%The FTM board records all triggers in a list, the so-called trigger-list.
839%This trigger-list comprises a maximum of 50 triggers. The first eleven words
840%are the same as in the static- and dynamic data block. During data-taking-,
841%calibration- and trigger runs, the Trigger-list is automatically sent to the
842%main control each time the 50 triggers are reached or the run is finished. In
843%addition, the Trigger-list can also be read-out by the main control with the
844%according command. In case the run finishes or is terminated, as well as when
845%read out manually, the trigger list might be shorter than 50 events.
846
847%% \begin{table}[h]
848%% \centering
849%\begin{longtable}[h]{|l|l|}\hline
850%address & content\\\hline\hline
851%0x000 & board ID bit 63 - 48 \\\hline
852%0x001 & board ID bit 47 - 32\\\hline
853%0x002 & board ID bit 31 - 16\\\hline
854%0x003 & board ID bit 15 - 0\\\hline
855%0x004 & firmware ID \\\hline
856%0x005 & Trigger counter at read-out time bits 31 .. 16 \\\hline
857%0x006 & Trigger counter at read-out time bits 15 .. 0\\\hline
858%0x007 & Time stamp counter at read-out time bits 47 .. 32 \\\hline
859%0x008 & Time stamp counter at read-out time bits 31 .. 16 \\\hline
860%0x009 & Time stamp counter at read-out time bits 15 .. 0 \\\hline
861%0x00A & spare \\\hline
862
863%0x00B & on-time counter at read-out time bits 47 .. 32 \\\hline
864%0x00C & on-time counter at read-out time bits 31 .. 16 \\\hline
865%0x00D & on-time counter at read-out time bits 15 .. 0 \\\hline
866
867%0x00E & 1st event Trigger-ID \\\hline
868%0x00F & 1st event Trigger-ID \\\hline
869%0x010 & 1st event Trigger-ID \\\hline
870%0x011 & 1st event Trigger primitives crate 0 \\\hline
871%0x012 & 1st event Trigger primitives crate 1 \\\hline
872%0x013 & 1st event Trigger primitives crate 2 \\\hline
873%0x014 & 1st event Trigger primitives crate 3 \\\hline
874%0x015 & 1st event Time stamp counter at trigger time bits 47 .. 32 \\\hline
875%0x016 & 1st event Time stamp counter at trigger time bits 31 .. 16 \\\hline
876%0x017 & 1st event Time stamp counter at trigger time bits 15 .. 0 \\\hline
877
878%0x018 & 2nd event Trigger-ID \\\hline
879%0x019 & 2nd event Trigger-ID \\\hline
880%0x01A & 2nd event Trigger-ID \\\hline
881%0x01B & 2nd event Trigger primitives crate 0 \\\hline
882%0x01C & 2nd event Trigger primitives crate 1 \\\hline
883%0x01D & 2nd event Trigger primitives crate 2 \\\hline
884%0x01E & 2nd event Trigger primitives crate 3 \\\hline
885%0x01F & 2nd event Time stamp counter at trigger time bits 47 .. 32 \\\hline
886%0x020 & 2nd event Time stamp counter at trigger time bits 31 .. 16 \\\hline
887%0x021 & 2nd event Time stamp counter at trigger bits 15 .. 0 \\\hline
888%... & ...\\\hline
889%0x1F8 & 50th event Trigger-ID \\\hline
890%0x1F9 & 50th event Trigger-ID \\\hline
891%0x1FA & 50th event Trigger-ID \\\hline
892%0x1FB & 50th event Trigger primitives crate 0 \\\hline
893%0x1FC & 50th event Trigger primitives crate 1 \\\hline
894%0x1FD & 50th event Trigger primitives crate 2 \\\hline
895%0x1FE & 50th event Trigger primitives crate 3 \\\hline
896%0x1FF & 50th event Time stamp counter at trigger time bits 47 .. 32 \\\hline
897%0x200 & 50th event Time stamp counter at trigger time bits 31 .. 16 \\\hline
898%0x201 & 50th event Time stamp counter at trigger bits 15 .. 0 \\\hline
899
900%% \end{longtable}
901%\caption{FTM trigger list}
902%\label{tab:FTM-trigger-list}
903%\end{longtable}
904
905\section{FTU list}
906\label{sec:FTU-List}
907When the FTM board receives the 'ping all FTUs' instruction, it sends a ping
908command to all FTU boards and gathers the FTU boards responses to a list. This
909list is called 'FTU list' and shown in table \ref{tab:FTU-list}. When the FTU
910list is complete, it is sent back via ethernet with the header defined in
911table~\ref{tab:FTM-header}.
912
913\begin{longtable}[h]{|l|l|}\hline
914address & content\\\hline\hline
9150x000 & total number of responding FTU boards\\\hline
9160x001 & number of responding FTU boards belonging to crate 0 \\\hline
9170x002 & number of responding FTU boards belonging to crate 1 \\\hline
9180x003 & number of responding FTU boards belonging to crate 2 \\\hline
9190x004 & number of responding FTU boards belonging to crate 3 \\\hline
9200x005 & active FTU list crate 0 \\\hline
9210x006 & active FTU list crate 1 \\\hline
9220x007 & active FTU list crate 2 \\\hline
9230x008 & active FTU list crate 3 \\\hline
9240x009 & address of first FTU board and number of sent pings until response\\\hline
9250x00A & DNA of first FTU board bit 63 ... 48\\\hline
9260x00B & DNA of first FTU board bit 47 ... 32\\\hline
9270x00C & DNA of first FTU board bit 31 ... 16\\\hline
9280x00D & DNA of first FTU board bit 15 ... 0\\\hline
9290x00E & CRC error counter reading of first FTU board\\\hline
9300x00F & address of second FTU board and number of sent pings until response\\\hline
9310x010 & DNA of second FTU board bit 63 ... 48\\\hline
9320x011 & DNA of second FTU board bit 47 ... 32\\\hline
9330x012 & DNA of second FTU board bit 31 ... 16\\\hline
9340x013 & DNA of second FTU board bit 15 ... 0\\\hline
9350x014 & CRC error counter reading of second FTU board\\\hline
936... & ...\\\hline
9370x0F8 & CRC error counter reading of last FTU board\\\hline
938\caption{FTU list}
939\label{tab:FTU-list}
940\end{longtable}
941
942In case there is no response to a 'ping' for a certain FTU address, there are
943up to two repetitions. If there is still no answer, only zeros are written
944into the FTU list for this particular board. A responding FTU board gets a
945regular entry, including the number of 'ping' sent until response. The number
946of pings is coded together with the FTU board address as shown in table
947\ref{tab:FTU-crate-number-and-address}. The two bits 'pings\_0' and 'pings\_1'
948contain the number of 'pings' until response of an FTU board (coded in
949binary). The 'DNA' of the FTU board is the device DNA \cite{ds557, ds610,
950 wp267, wp266} of the FPGA on the responding FTU board. This is a unique 57
951bit serial number unambiguously identifying every Xilinx FPGA. In the most
952significant word (bit 63 ... 48) bits 63 down to 57 are filled with zeros.
953
954\begin{table}[h]
955\centering
956\begin{tabular}{|l|l|l|l|l|l|l|l|l|l|l|l|l|}\hline
957Bit & 15 ... 10 & 9 & 8 & 7 & 6 & 5 & ... & 0 \\\hline
958Content & x ... x & pings\_1 & pings\_0 & x & x & A5 & ... & A0 \\\hline
959\end{tabular}
960\caption{Address of FTU board and number of pings until response. In case
961 there is no response at all, this number is set to 0.}
962\label{tab:FTU-crate-number-and-address}
963\end{table}
964
965\chapter{FTU communication error handling}
966\label{cha:Error-handling}
967
968When the FTM board is communicating with a FTU board via RS-485, the FTU board
969has to respond within 2\,ms (after the last byte was transmitted). If this
970timeout expires, or the response sent back by the FTU board is incorrect, the
971FTM resends the datapacket after the timeout. If this second attempt is still
972unsuccessful, a third and last attempt will be made by the FTM board. An error
973message will be sent to the FTMcontrol whenever a FTU board does not send a
974correct answer after the first call by the FTM board. This message (see
975table~\ref{tab:error-message}) contains, after the standard header (see
976table~\ref{tab:FTM-header}), the number of calls until response (0 if no
977response at all), and the corresponding data packet which was sent to the FTU
978board. In order to avoid massive error messages for e.g. test setups with
979single FTUs, the 'active FTU list' can be employed to disable FTUs from the
980bus. In that case the FTM will not try to contact the corresponding boards.
981
982\begin{table}[h]
983 \centering
984 \begin{tabular}{|l|l|}\hline
985 word no & content\\\hline\hline
986 0x000 & number of calls until response (0 if no response at all)\\\hline
987 0x001 ... 0x01C & slow control data packet sent to FTU (28 words/bytes)\\\hline
988 \end{tabular}
989 \caption{FTU communication error message (after standard header); for a
990 description of the FTU data package, see \cite{FTUspecs}.}
991 \label{tab:error-message}
992\end{table}
993
994%---------------------------------------------------------------------------------
995
996\bibliographystyle{unsrt}
997%\bibliography{FTM-Com}
998
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