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The Constant Fraction Discriminators CFD8c, CFD7x, CFD4c, CFD1c and CFD1x (11.0.1701.1)  

3b.2

 

Principles of the CFD circuit 

It is important to note that an optimal operation of the 

RoentDek

 CFD units requires optimal settings of the parameters  

 

 

Threshold level (Th) 

 

Walk level (Z) 

 

CFD delay 

 

CFD fraction 

 

with respect to the input signal properties. This will be explained in the following.  

 

 

Figure 3.3b: Front panel inputs, test points and control potentiometers , not shown is the veto input  

and the 

CFD fraction

 potentiometer being on the front panel for c and x versions (see Figure 3.14)

 

If a signal as shown in Figure 3.4b (left)

*

  is turned into a bipolar signal (right) by an appropriate electronic chain it can be 

shown that the zero-crossing of the bipolar signal does not jitter in time as function of the input pulse height.  

The CFD circuit consists of two parts:  

The “

analogue

” 

circuit

 produces this bipolar signal from a unipolar input signal: A resistor-divider splits the signal into two 

with different relative pulse heights. The ratio of the pulse heights (

CFD fraction

) is determined by the choice of fix resistors 

or a potentiometer (as in case of the 

RoentDek

 

CFDs

). While one of the signals is inverted later on, the other experiences a 

certain delay (

CFD delay

) before both signals are superimposed to form the bipolar signal. On the 

RoentDek

 

CFDs

, this 

delay is formed by an external coax cable (LEMO 00 series) connected between the front-panel sockets labelled 

Delay

. The 

bipolar signal can be observed on the analogue walk monitor output socket labelled M

a

 (damped by a factor of 10). The 

CFD 

fraction

 can be adjusted via a potentiometer on the front panel side panel (

CFD4b

: side panel, 

CFD1b

 and 

CFD8b

: on the lid). 

 

Figure 3.4b: Schematics of a CFD analogue chain 

Figure 3.6b shows the digital circuit chain of two comparators and a logical AND-gate: One comparator switches to “high” 

when the input signal exceeds a certain (adjustable) reference value (the

Threshold level)

 and produces a norm signal (this is 

how a simple “leading-edge” discriminator unit operates). When the input signal level is below the 

Threshold level

, its output 

returns to “low”. Ideally, the 

Threshold level

 is set above electronic noise but low enough to register even the smallest valid input 

signals. 

 

                                                           

*

 Note that for 

RoentDek

 

CFDs

 the input signal polarity is negative 

Содержание CFD1c

Страница 1: ...Dek Handels GmbH Supersonic Gas Jets Detection Techniques Data Acquisition Systems Multifragment Imaging Systems The RoentDek Constant Fraction Discriminators CFD8c CFD7x CFD4c CFD1c and CFD1x 11 0 17...

Страница 2: ...Kernphysik Max von Laue Str 1 D 60438 Frankfurt am Main Germany Web Site www roentdek com WEEE DE48573152 Product names used in this publication are for identification purposes only and may be tradema...

Страница 3: ...3 CFD fraction 12 3b 3 4 Walk level 13 3b 3 5 Output signal width 14 3B 4 THE VETO OPTION 14 3b 4 1 Accessing the jumpers in CFD1c CFD1x 16 3b 4 2 Accessing the jumpers in CFD8c and CFD7x 16 3b 4 3 A...

Страница 4: ...Page 4 of 25 The Constant Fraction Discriminators CFD8c CFD7x CFD4c CFD1c and CFD1x 11 0 1701 1...

Страница 5: ...Constant Fraction DiscriminatorsCFD8b CFD4b and CFD1b 11 0 1701 1 Page 5 of 25...

Страница 6: ...odules containing such boards please review first Chapters 3b 1 to 3b 3 and then refer to Chapter 3b 7 to learn about the difference between the standard CFD and the RoentDek bCFD settings 3b 1 Genera...

Страница 7: ...weight 0 8 kg with an external 12 V DC mains adapter for use with 100 250 V AC sockets The power consumption is max 0 5 A at 12 V DC 6 W or max 0 7 A at 12 V DC 10 W for the CFD1x The CFD4c has the s...

Страница 8: ...fraction is determined by the choice of fix resistors or a potentiometer as in case of the RoentDek CFDs While one of the signals is inverted later on the other experiences a certain delay CFD delay...

Страница 9: ...he signals have to be verified on an oscilloscope The CFD Fraction can be adjusted by another potentiometer labelled Fr on the front panel CFD4b CFD1b side panel CFD8b top lid see Figure 3 6b Figure 3...

Страница 10: ...s damped by a factor of 10 For achieving the ideal settings it is first of all important to note that the CFD operates best in all respects and yields the optimal temporal resolution if the input sign...

Страница 11: ...delay D of 5 5 ns Note that the RoentDek CFDs will not operate without connecting an external delay cable bridge If the pulse rise time RT is defined as the time from reaching 10 to 90 of the signal m...

Страница 12: ...livers the CFD with a standard CFD fraction setting of about 0 35 The CFD fraction can be varied between 0 15 and 1 via a potentiometer In order to observe and quantify the CFD fraction ratio on the o...

Страница 13: ...during the bipolar signal s crossover while fluctuating almost equally between high and low states before and long after the signal due to electronic noise on the line not visible in the pictures If...

Страница 14: ...idth bridges of the internal circuit see Figure 3 5b With the jumper in place the maximum width is increased to 2000 ns Please contact RoentDek if you are in need of the optional jumpers Obviously a s...

Страница 15: ...15b Trace of the input signal to the Veto socket upper trace and signal traces of CFD timing signals lower trace integrated over many events for Veto left and Gating mode right In order to work reliab...

Страница 16: ...he front panel 3b 4 2 Accessing the jumpers in CFD8c and CFD7x I Disconnect the mains power supply II On the rear panel remove all five screws red circles Please note that different types and sizes of...

Страница 17: ...ear front panel and fix them with all screws and hex bolts 3b 4 3 Accessing the jumpers in CFD4c I Remove all six screws from the right side panel marked in red see Figure 3 20b Figure 3 20b Side pane...

Страница 18: ...oscope see Figure 3 21b If a CFD is used for operating a RoentDek delay line detector or similar device these pre trigger events result in a distinct structure in the time sum spectrum see Figure 3 21...

Страница 19: ...neighbours 3b 6 The CFDx pulse height determination option The CFDx function is an add on circuit that allows measuring the signal s pulse height The pulse height information is coded as a time delay...

Страница 20: ...er trace ramp monitor output the Ramp switch is turned off here Signals are triggered on the CFD timing output signal trace not shown Left and right pictures were obtained with two different cable len...

Страница 21: ...Dx signal This is indicated in Figure 3 26b The ramp slope is about 1 V per 12 ns giving an almost linear correspondence between pulse height and time delay with a typically 10 to 20 ns offset for pul...

Страница 22: ...iming signal with a RoentDek TDC8HP The same spectrum could be recorded by plotting the time difference between trailing and leading transitions of the CFDx output It is advisable to mark the pulse he...

Страница 23: ...se heights will not be registered Please contact RoentDek for advice unless you have received a properly matched system with bFAMP for a certain delay line read out anode Timing signals off the MCP co...

Страница 24: ...3 12B SIGNAL TRACES AS IN FIGURE 3 8B LEFT WITH THE WALK LEVEL SET TO THE BASELINE OF THE INPUT SIGNALS LEFT PICTURE AND SLIGHTLY TOWARDS THE POSITIVE SIDE WHERE THE NOISE TRIGGERS BEGIN TO VANISH RIG...

Страница 25: ...DTH POTENTIOMETER SETTING LOWER TRACE RAMP MONITOR ALL TRACES TRIGGERED ON THE STOP SIGNAL THE STOP SIGNAL SHOULD BE USED IF THERE IS A SPARE TDC CHANNEL AVAILABLE 21 FIGURE 3 27B AS FIGURE 3 25B RIGH...

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