GSI TRB3: Difference between revisions
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== Documentation == | == Documentation == | ||
[http://trb.gsi.de/ Main TRB3 webpage] | * [http://trb.gsi.de/ Main TRB3 webpage] | ||
* [http://jspc29.x-matter.uni-frankfurt.de/docu/trb3docu.pdf Main TRB3 Manual] | |||
[http://jspc29.x-matter.uni-frankfurt.de/docu/trb3docu.pdf Main TRB3 Manual] | * [[Media:Trb3docu-2018aug10.pdf]] local copy of the manual | ||
* [[Media:Trb3docu.pdf]] local copy of the manual | |||
* [[Media:trb3.pdf]] local copy of the schematics | |||
* [[Media:4conn.pdf]] schematics 4 LVDS connector add-on board (GSI-AD ADDON_4CONN2) | |||
* [[Media:trbdist1-SCM.pdf]] [[Media:trbdist2.pdf]] [[Media:trbdist3-SCM.pdf]] schematics for external trigger and clock interface boards | |||
== Hardware Information == | == Hardware Information == | ||
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</pre> | </pre> | ||
e) "Ping of death" somehow ping board to reboot it: | e) Check the status of the clock | ||
Check bit 8 of register 0xd300. | |||
This indicates that an external clock is being used | |||
<pre> | |||
[agtdc@daq16 triumf_trb171]$ trbcmd r 0xc001 0xd300 | |||
0xc001 0x00000101 | |||
</pre> | |||
This indicates that an internal clock is being used | |||
<pre> | |||
[agtdc@daq16 triumf_trb171]$ trbcmd r 0xc001 0xd300 | |||
0xc001 0x00000001 | |||
</pre> | |||
f) "Ping of death" somehow ping board to reboot it: | |||
<pre> | <pre> | ||
ping -pc001 trb171 | ping -pc001 trb171 | ||
</pre> | </pre> | ||
== Updating TRB3 firmware == | |||
Based on instructions from Michael | |||
General points: | |||
* Take care that you have a stable setup with the power-supply stable and cooling ok, as if you turn off the board while reprogramming you need a programming cable to recover the FPGA. | |||
* List of available firmware files are here: | |||
https://jspc29.x-matter.uni-frankfurt.de/trbweb/?action=page&url=design-files | |||
Steps to flash | |||
1) Get firmware. Ie: | |||
<pre> wget http://jspc29.x-matter.uni-frankfurt.de/bitfiles/trb3_periph_padiwa_tdc_32_stretch_triggerlogic28-4_20181024.bit </pre> | |||
2) reflashing is done via: | |||
<pre> trbflash program 0x<TRB-address-of-FPGA> ./trb3_periph_padiwa_tdc_32_stretch_triggerlogic28-4_20181024.bit | |||
</pre> | |||
<pre> | |||
trbflash program 0x0102 ./trb3_periph_padiwa_tdc_32_stretch_triggerlogic28-4_20181024.bit | |||
trbflash program 0x0103 ./trb3_periph_padiwa_tdc_32_stretch_triggerlogic28-4_20181024.bit </pre> | |||
3) after a successful flash and verify (automatic): | |||
<pre> trbcmd reload 0x<TRB-address-of-FPGA> </pre> | |||
4) But do it one FPGA after the other, if you do it the first time. | |||
You can also reprogramm all of them at once with a broadcast address. | |||
== Konstantin's notes == | |||
=== TRB3 grounding === | |||
to avoid damage to the DC-coupled trigger input, TRB3 PCB should be grounded to the same | |||
ground as the device driving this input (VME-CDM in this case). On the TRB3 side, we attach | |||
the ground wire to one of the PCB mounting holes (confirmed ground). On the other end, it should | |||
be attached to the VME crate ground. | |||
the clock input is AC coupled and probably no affected by grounding problems. | |||
the esata splitter should also be grounded, see below. | |||
=== esata spliter in use by ALPHA-g === | |||
CDM --- minisas --- 4-esata-flail --- esata --- ALPHA-T splitter --- 2x cat6 --- 2xRJ45 | |||
ALPHA-T esata splitter: | |||
* use 7ft cat6 patch cable, 568B wiring (568A will work, but color coding is not the same) | |||
* cat6 RJ45 green pair solder to splitter clock side | |||
* cat6 RJ45 green pair solder to splitter trigger side | |||
* ground wire of same length solder to esata ground, other end attach to TRB3 PCB mounting hole or other good ground. | |||
=== second trigger input === | |||
According to schematics and documentation, RJ45 "trigger" connector has 2 trigger inputs, | |||
normal input via the "green pair" and second input via the "orange pair". | |||
Switching between these inputs is done by "TRIGGER_SELECT" FPGA output acting on the "IN_SEL" pin of the CDCLVD1216 LVDS mux ([[Media:Cdclvd1216.pdf]] datasheet). | |||
This "TRIGGER_SELECT" signal is not listed in the documentation, but I confirm with voltmeter at J28 test point that it's output is same as bit 0 of register 0xd300. writing "1" sets voltage to 2.5V, writing "0" sets it to 0V. | |||
However, in either state, it has no effect on the trigger input. One would expect that the normal trigger will stop if the lvds mux is switched to the second input. Actually regardless of "TRIGGER_SELECT" state, the normal trigger input is always active (oscillates if connected to unterminated/ungrounded RJ45 cable), the second trigger input never produces any trigger counts. | |||
this is a mystery. | |||
== ZZZ == | |||
ZZZ |
Latest revision as of 15:25, 31 May 2021
TRB3 is an FPGA-TDC board made and sold by GSI. It can achieve ~20ps timing resolution
Documentation
- Main TRB3 webpage
- Main TRB3 Manual
- Media:Trb3docu-2018aug10.pdf local copy of the manual
- Media:Trb3docu.pdf local copy of the manual
- Media:trb3.pdf local copy of the schematics
- Media:4conn.pdf schematics 4 LVDS connector add-on board (GSI-AD ADDON_4CONN2)
- Media:trbdist1-SCM.pdf Media:trbdist2.pdf Media:trbdist3-SCM.pdf schematics for external trigger and clock interface boards
Hardware Information
Power
The TRB3 runs off 50V DC power. The TRB3 needs a fan in order to operate. Between the fan and the TRB3 they draw ~0.5A on 50V.
Clock and Trigger
Michael Traxler provided the following picture of clock and trigger circuitry:
Michael also provides following details
Clock:
- system clock frequency of 200MHz can be taken either from the internal oscillator, or via the second LVDS pair (pin 3 and 6) of the connector "RJ-45-Clock". They are distributed to all 5 FPGAs to the primary-clock-input.
- In all "modern" FPGA designs (since several years) you don't have to do anything in registers to use the external clock. The scheme is simple: When an external clock is available and stable and the PLL locks to it at power up, the external clock is used. If not, the internal clock is used.
Trigger:
- If you have a CTS (or a single TRB3 setup) the trigger is generated in the CTS, from external tigger sources. This you can see in Table 27 in the TRB3-manual (currently page 75). For instance, one of the external trigger signals is on pair 2 of the trigger RJ45 connector
- So, for the CTS, there are 4 different inputs available on the two RJ45 connectors, which all can be used at the same time. If you need more, you can add a CTS-AddOn on the backside of the TRB3 and then you have many more trigger inputs. Each input will generate a certain "trigger type" data word in the data stream to distinguish between the trigger inputs.
TDC calibration
The concept of the FPGA-TDC calibration is described here:
http://dabc.gsi.de/doc/dabc2/hadaq_tdc_calibr.html
One important summary from that document: we require ~1e5 random hits for every channel in order to build up an individual fine counter calibration for each channel.
Computer and Software Setup Instructions
Currently have gotten the TRB3 working on three different configurations. On this page we provide information that is generic to each setup. The links provide instructions for the parts of the operation that are unique to each setup:
1) A GSI-provided readout package (and analysis package) which runs on OpenSuse. See TRB3 GSI Opensuse instructions.
2) A MIDAS-based readout on an Opensuse machine. No instructions.
3) A MIDAS-based readout on a Centos-7 machine. See TRB3 Centos-7 instructions.
On this page we provide information that is generic to each setup. The links provide instructions for the parts of the operation that are unique to each setup:
We setup TRB3 on a private network. So need machine with second ethernet port.
Useful TRB3 commands
a) Get IDs for TRB3 FPGAs (1 central FPGA and 4 FPGAs for TDCs):
trb3_user@linux-klyr:~/lindner> trbcmd i 0xffff 0xc001 0xe1000006e937ac28 0x05 0x0100 0x9c000006e937a028 0x00 0x0101 0x91000006e95e8328 0x01 0x0102 0x75000006e9383128 0x02 0x0103 0xe6000006e96e5228 0x03
The four FPGAs that actually make TDCs are numbered 0x100, 0x101, 0x102, 0x103.
b) Print out raw TDCs for the events that are coming in through event builder
hldprint localhost:6789 -onlytdc 0x0100 -num 0
c) Print out raw TDCs for events in file
hldprint //data/trb3_data/pulser17342114715.hld -onlytdc 0x0100 -num 0
d) Print out raw data stream from EB
hldprint localhost:6789 -raw
e) Check the status of the clock
Check bit 8 of register 0xd300.
This indicates that an external clock is being used
[agtdc@daq16 triumf_trb171]$ trbcmd r 0xc001 0xd300 0xc001 0x00000101
This indicates that an internal clock is being used
[agtdc@daq16 triumf_trb171]$ trbcmd r 0xc001 0xd300 0xc001 0x00000001
f) "Ping of death" somehow ping board to reboot it:
ping -pc001 trb171
Updating TRB3 firmware
Based on instructions from Michael
General points:
- Take care that you have a stable setup with the power-supply stable and cooling ok, as if you turn off the board while reprogramming you need a programming cable to recover the FPGA.
- List of available firmware files are here:
https://jspc29.x-matter.uni-frankfurt.de/trbweb/?action=page&url=design-files
Steps to flash
1) Get firmware. Ie:
wget http://jspc29.x-matter.uni-frankfurt.de/bitfiles/trb3_periph_padiwa_tdc_32_stretch_triggerlogic28-4_20181024.bit
2) reflashing is done via:
trbflash program 0x<TRB-address-of-FPGA> ./trb3_periph_padiwa_tdc_32_stretch_triggerlogic28-4_20181024.bit
trbflash program 0x0102 ./trb3_periph_padiwa_tdc_32_stretch_triggerlogic28-4_20181024.bit trbflash program 0x0103 ./trb3_periph_padiwa_tdc_32_stretch_triggerlogic28-4_20181024.bit
3) after a successful flash and verify (automatic):
trbcmd reload 0x<TRB-address-of-FPGA>
4) But do it one FPGA after the other, if you do it the first time. You can also reprogramm all of them at once with a broadcast address.
Konstantin's notes
TRB3 grounding
to avoid damage to the DC-coupled trigger input, TRB3 PCB should be grounded to the same ground as the device driving this input (VME-CDM in this case). On the TRB3 side, we attach the ground wire to one of the PCB mounting holes (confirmed ground). On the other end, it should be attached to the VME crate ground.
the clock input is AC coupled and probably no affected by grounding problems.
the esata splitter should also be grounded, see below.
esata spliter in use by ALPHA-g
CDM --- minisas --- 4-esata-flail --- esata --- ALPHA-T splitter --- 2x cat6 --- 2xRJ45
ALPHA-T esata splitter:
- use 7ft cat6 patch cable, 568B wiring (568A will work, but color coding is not the same)
- cat6 RJ45 green pair solder to splitter clock side
- cat6 RJ45 green pair solder to splitter trigger side
- ground wire of same length solder to esata ground, other end attach to TRB3 PCB mounting hole or other good ground.
second trigger input
According to schematics and documentation, RJ45 "trigger" connector has 2 trigger inputs, normal input via the "green pair" and second input via the "orange pair".
Switching between these inputs is done by "TRIGGER_SELECT" FPGA output acting on the "IN_SEL" pin of the CDCLVD1216 LVDS mux (Media:Cdclvd1216.pdf datasheet).
This "TRIGGER_SELECT" signal is not listed in the documentation, but I confirm with voltmeter at J28 test point that it's output is same as bit 0 of register 0xd300. writing "1" sets voltage to 2.5V, writing "0" sets it to 0V.
However, in either state, it has no effect on the trigger input. One would expect that the normal trigger will stop if the lvds mux is switched to the second input. Actually regardless of "TRIGGER_SELECT" state, the normal trigger input is always active (oscillates if connected to unterminated/ungrounded RJ45 cable), the second trigger input never produces any trigger counts.
this is a mystery.
ZZZ
ZZZ