Xrf spi debug
Spi communications during System Check (Shutter Cal)
CalibrateDetector function is main loop that runs the shutter cal process. It does a bunch of memory allocations, close_shutter calls and it calls <code>InitShaperXL3</code>. After this the filter wheel will be moved to the correct position and the xray tube will be started. Now we start <code>SpectraView2_segger</code> and drop into the looping function <code>GetSpectra</code> which is the function that reads data from the fpga and determines when the process is done.
Setting of Shapers
<code>InitShaperXL3</code> sets up a local structure with shaper parameters based on the current detector being used. This function also calls <code>adjustDetectorShapers</code> and <code>SetShaperXL3</code>. This function then terminates.
<code>adjustDetectorShapers</code> modify's some of the parameters based on a few more conditions. Why this is not included in the previous function is beyond me... All parameters are in system ram, still nothing has been updated in the actual fpga registers.
<code>SetShaperXL3</code> makes some addition modifications to parameters and creates a few new ones based on other but with addtional offsets (wtf), it then calls <code>SetShaperUsingSPI</code>. There is also the ability to debug output a collection of probably important paramters: <pre> sprintf(buf,"SLOW_RISE_TIME:%d\r\n",SHS.SLOW_RISE_TIME); sprintf(buf,"GATE_RECOVERY:%d\r\n",SHS.GATE_RECOVERY); sprintf(buf,"RTD_RISE_TIME:%d\r\n",SHS.RTD_RISE_TIME); sprintf(buf,"RTD_FLAT_TOP_RTM:%d\r\n",SHS.RTD_FLAT_TOP_RTM); sprintf(buf,"PEAK_TIME:%d\r\n",SHS.PEAK_TIME); sprintf(buf,"AFTER_PEAK_GUARD:%d\r\n",SHS.AFTER_PEAK_GUARD); sprintf(buf,"DT_EXTENSION:%d\r\n",SHS.DT_EXTENSION); sprintf(buf,"SLOW_EXTENSION:%d\r\n",SHS.SLOW_EXTENSION); sprintf(buf,"FAST_EXTENSION:%d\r\n",SHS.FAST_EXTENSION); sprintf(buf,"SLOW_BIN_GAIN:%d\r\n",SHS.SLOW_BIN_GAIN); sprintf(buf,"SLOW_FINE_GAIN:%d\r\n",SHS.SLOW_FINE_GAIN); </pre>
<code>SetShaperUsingSPI</code>, I found something that actually writes stuff to the fpga. We start off reading <code>REG_ADDR_2</code> and clearing bit 8.
<pre> usDetector = Read_Single ( (REG_ADDR_2) ); usDetector &= ~(1<<8); // First detector
Write_Single( (REG_ADDR_2),usDetector ); Write_Single( (REG_ADDR_17),SHS.GATE_WIDTH_EXT); Write_Single( (REG_ADDR_18),SHS.GATE_RECOVERY); Write_Single( (REG_ADDR_16),SHS.ADC_OFFSET); Write_Single( (REG_ADDR_19),SHS.FAST_RISE_TIME +256*(SHS.FAST_RISE_TIME+SHS.FAST_FLAT_TOP)) ;
if (SHS.CUSP_TRAP)
{
usReg7 = ((short)(SHS.SLOW_FLAT_TOP))|0x8000;
}
else
{
usReg7 = ((short)(SHS.SLOW_FLAT_TOP))&0x7FFF;
}
//bits 12 to 10 which have been moved to a new register Reg 31
Write_Single( (REG_ADDR_20), usReg7);
Write_Single( (REG_ADDR_21) ,SHS.SLOW_RISE_TIME);
Write_Single( (REG_ADDR_22) ,SHS.SLOW_EXTENSION + 256*SHS.FAST_EXTENSION);// check it with the old one and send
Write_Single( (REG_ADDR_23),SHS.FAST_THRESH_LOW);
Write_Single( (REG_ADDR_24),SHS.FAST_THRESH_HIGH);
Write_Single( (REG_ADDR_25),SHS.SLOW_THRESH_LOW);
Write_Single( (REG_ADDR_26),SHS.SLOW_THRESH_HIGH);
Write_Single( (REG_ADDR_27),SHS.SLOW_BLR_TAU + 256*SHS.FAST_BLR_TAU);
Write_Single( (REG_ADDR_28),SHS.AFTER_PEAK_GUARD );
Write_Single( (REG_ADDR_29),SHS.PEAK_TIME);
Write_Single( (REG_ADDR_30),FPGA_GAIN); // for gain control (00->gain=1.05, 01 ->gain=2, 02 -> gain=4)
Write_Single( (REG_ADDR_31),SHS.SLOW_BIN_GAIN);
Write_Single( (REG_ADDR_32),SHS.SLOW_FINE_GAIN);
Write_Single( (REG_ADDR_33),SHS.DT_EXTENSION);
- if 1//def RTD
usReg34 = SHS.RTD_RISE_TIME; Write_Single(REG_ADDR_34, usReg34);// Setting the RTD RISE TIME usReg35 = SHS.RTD_FLAT_TOP_RTM;//usReg34 + ( usReg19 & 0xFF) + ( usReg19/256 ); Write_Single(REG_ADDR_35, usReg35);
- endif
//Clear Spectrum is optional here
ClearSpectrum_SPI ( );
usTempData = Read_Single ( (REG_ADDR_2) ); usTempData &= ~0x0002; //Disable acquisition Write_Single ( (REG_ADDR_2), usTempData ); usTempData = Read_Single ( (REG_ADDR_2) ); usTempData |= (1<<7); //Enable RTD
Write_Single ( (REG_ADDR_2), usTempData | 0x0000 );// This selects Slow Shaper at the output of the DAC board - default
</pre>
Getting spectra
Ok, so we start by disabling spectral acquisition <code>startSpectrum(FALSE)</code> and then call <code>InitShaperXL3</code>. We then zero out localSpecra buffer, initialize a bunch of local variables and get the current (starting) realtime and livetime values for future use.
Register definitions
| register | description |
|---|---|
| REG_ADDR_0 | Frequency value (set to 9?) Might readback some testscope2 block data |
| REG_ADDR_1 | Delay value (set to 20?), bit 15 something to do with scope data |
| REG_ADDR_2 | shaper control |
| bit 11 unused, bit 10 rtd shaper enable, bit 9 slow shaper enable, bit 8 fast shaper enable | |
| bit 7 rtd enable, bit 6 unused, bit 5 unused, bit 4 start timer (appears to be disconnected in 8474) | |
| bit 3 unused, bit 2 unused, bit 1 enable acquisition (and timers), bit 0 reset blr | |
| REG_ADDR_3 | Revision register (DD[3][15..0] |
| REG_ADDR_4 | Live Time LSB <code>GetCurrentRealAndLiveTime</code> Pulse processor state machine is halted until these are non-zero. These values should be initialized to 0xffff and this will allow the pulse processor to run. (countdown). |
| REG_ADDR_5 | Live Time MSB <code>GetCurrentRealAndLiveTime</code> Pulse processor state machine is halted until these are non-zero. These values should be initialized to 0xffff and this will allow the pulse processor to run. (countdown). |
| REG_ADDR_6 | Real Time LSB <code>GetCurrentRealAndLiveTime</code> Pulse processor state machine is halted until these are non-zero. These values should be initialized to 0xffff and this will allow the pulse processor to run. (countdown). |
| REG_ADDR_7 | Real Time MSB <code>GetCurrentRealAndLiveTime</code> Pulse processor state machine is halted until these are non-zero. These values should be initialized to 0xffff and this will allow the pulse processor to run. (countdown). |
| REG_ADDR_8 | Live Time LSB <code>GetRealAndLiveTime</code> (latched values) |
| REG_ADDR_9 | Live Time MSB <code>GetRealAndLiveTime</code> (latched values) |
| REG_ADDR_10 | Real Time LSB <code>GetRealAndLiveTime</code> (latched values) |
| REG_ADDR_11 | Real Time MSB <code>GetRealAndLiveTime</code> (latched values) |
| REG_ADDR_12 | Current fast value (read only) |
| REG_ADDR_13 | Current slow value (read only) |
| REG_ADDR_14 | unused |
| REG_ADDR_15 | unused |
| REG_ADDR_16 | adc offset |
| REG_ADDR_17 | gate width extension |
| REG_ADDR_18 | gate recovery |
| REG_ADDR_19 | bits 0-7 fast rise time, bits 8-15 fast flat top + fast rise time |
| REG_ADDR_20 | bit 15 cusp trap, 0-14 slow flat top |
| REG_ADDR_21 | slow rise time |
| REG_ADDR_22 | bits 0-7 slow extension, bits 8-15 fast extension |
| REG_ADDR_23 | fast threshold low, typically set to 1.5*current fast value |
| REG_ADDR_24 | fast threshold high, typically set to 2.0*current fast value |
| REG_ADDR_25 | slow threshold low, typically set to 1.5*current slow value |
| REG_ADDR_26 | slow threshold high, typically set to 2.0*current slow value |
| REG_ADDR_27 | bits 0-7 slow blr tau, bits 8-15 fast blr tau |
| REG_ADDR_28 | after peak guard |
| REG_ADDR_29 | peak time |
| REG_ADDR_30 | fpga gain, gain control (00->gain=1.05, 01 ->gain=2, 02 -> gain=4) |
| REG_ADDR_31 | slow bin gain |
| REG_ADDR_32 | slow fine gain |
| REG_ADDR_33 | dt extension |
| REG_ADDR_34 | rtd rise time |
| REG_ADDR_35 | rtd flat top rtm |
| REG_ADDR_36 | bit 0 Bank select (0=bank_0, 1=bank_1), bit 1 clear on read (0=clear, 1=no clear) |
| REG_ADDR_37 | |
| REG_ADDR_38 | |
| REG_ADDR_39 | |
| REG_ADDR_40 | |
| REG_ADDR_41 | |
| REG_ADDR_42 | |
| REG_ADDR_43 | |
| REG_ADDR_44 | |
| REG_ADDR_45 | |
| REG_ADDR_46 | |
| REG_ADDR_47 | |
| REG_ADDR_48 | |
| REG_ADDR_49 | |
| REG_ADDR_50 | |
| REG_ADDR_51 | |
| REG_ADDR_52 | |
| REG_ADDR_53 | |
| REG_ADDR_54 | |
| REG_ADDR_55 | |
| REG_ADDR_56 | |
| REG_ADDR_57 | |
| REG_ADDR_58 | |
| REG_ADDR_59 | |
| REG_ADDR_60 | |
| REG_ADDR_61 | |
| REG_ADDR_62 | |
| REG_ADDR_63 | |
| REG_ADDR_64 | |
| REG_ADDR_65 | |
| REG_ADDR_66 | |
| REG_ADDR_67 | |
| REG_ADDR_68 | |
| REG_ADDR_69 |