gpamela/gpspe/gpucollection.F

*-- Author :    Elena Taddei-Sergio Bottai 09/08/2005
      
        SUBROUTINE GPUCOLLECTION(np,nt)

***************************************************************************
*                                                                         *
*                                                                         *
*                                                                         *
*      Here we calculate the signal appearing on each ADC channel         *
*      starting from the charge collected on every strip of the silicon   *
*      sensor. Noise is kept from data of beam test. Capacitive coupling  *
*      between strips and energy to ADC calibration are introduced too.   *
*                                                                         *
*                                                                         *
* Called by: GPDSPE                                                       *
*                                                                         *
***************************************************************************

#include "gpstripspe.inc" 

c
c new strip capacitance simulation 19/02/09 S. Bottai
c        
c
        dimension stripqxtanti(nstripx)
        dimension stripqytanti(nstripy)
        

********zeroing**************

        do i=1,nstripx
            stripqxtanti(i)=0.
        enddo
        do i=1,nstripy
           stripqytanti(i)=0.
        enddo
        
***************************
        if(NT.eq.1.or.NT.eq.4) LADD=1
        if(NT.eq.2.or.NT.eq.5) LADD=2
        if(NT.eq.3.or.NT.eq.6) LADD=3   
        
*
*      Odd strip, X side --> charge shared between adjacent strips
*      EFFCOUPL          --> coupling efficiency (capacitance to backplane =0?)
*      SHIFTMASK         --> asymmetry in charge division on X view
*                            different in each sensor (mask)
        
         
        do j=(1+8),(nstripx-7),2
                proxtanti(np,nt,j-1)=
     +          proxtanti(np,nt,j-1)+
     +          0.5*effcoupl*proxtanti(np,nt,j)*(1.-shiftmask) 

                proxtanti(np,nt,j+1)=
     +          proxtanti(np,nt,j+1)+
     +          0.5*effcoupl*proxtanti(np,nt,j)*(1.+shiftmask)
            proxtanti(np,nt,j)=0.
         enddo  


*
*      Capacitive coupling: a fraction of the charge arriving at one strip
*      appears at the output of the neighbouring amplifiers
*      This fraction is about Cis/Cdec, where Cis is the interstrip 
*      capacitance and Cdec is the decoupling capacitance (see Turchetta)
*      An algorithm has been chosen that is precise for low values of the 
*      capacitive coupling, i.e. if the INDUCED charge on a given strip 
*      is little compared with the COLLECTED one.
*


******************** X side *************************
                            
        c=cistrx/cdec
        c2=cistrx2/cdec


        do j=8,nstripx-6,2       ! only even strips on X side
CV            jm2=1
CV            IF(j-2.lt.8) jm2=0
CV            jp2=1
CV            IF(j+2.gt.(nstripx-6)) jp2=0
CV            jm4=1
CV            IF(j-4.lt.8) jm4=0
CV            jp4=1
CV            IF(j+4.gt.(nstripx-6)) jp4=0

            
            stripqxtanti(j)=proxtanti(np,nt,j)
            SUMF=0.
ccc            DO KK=1,15  
            DO KK=1,4
            KF=KK*2
            IF(KK.EQ.1) FN=F1
            IF(KK.EQ.2) FN=F2
            IF(KK.EQ.3) FN=F3
            IF(KK.EQ.4) FN=F4
            IF(KK.GE.5) FN=F1/KK
              IF((J-KF).GE.8) THEN 
                 stripqxtanti(j)=stripqxtanti(j)+FN*proxtanti(np,nt,j-KF)
                 SUMF=SUMF+FN
              ENDIF
              IF((J+KF).LE.(nstripx-6)) THEN
                 stripqxtanti(j)=stripqxtanti(j)+FN*proxtanti(np,nt,j+KF)
                 SUMF=SUMF+FN
              ENDIF
            ENDDO

            stripqxtanti(j)=stripqxtanti(j)-SUMF*proxtanti(np,nt,j)
            
cv          stripqxtanti(j)=proxtanti(np,nt,j)*(1.-2.*(c+c2))+     
cv     +   c*(1.-2.*c)*(jm2*proxtanti(np,nt,j-2)
cv     +   +jp2*proxtanti(np,nt,j+2))+
cv     +  (c**2)*(jm4*proxtanti(np,nt,j-4)*(1.+c2/(c**2))+
cv     +   2.*proxtanti(np,nt,j)+jp4*proxtanti(np,nt,j+4)*(1.+c2/(c**2)))
        

            if(stripqxtanti(j).gt.1.e-8) then

              IVA1=INT((J/2-1)/128)+1
              IF(badva1(NP*2,LADD,IVA1).EQ.1) THEN               
               NSTRPX=NSTRPX+1 
               floatadcx=stripqxtanti(j)*xcalib
               IF(NSTRPX.GT.MAXSTR) THEN
                 WRITE(6,*) 'ERROR - NSTRPX > MAXSTR'
                 NSTRPX=MAXSTR
               ENDIF          
               NPSTRIPX(NSTRPX)=NP
               NTSTRIPX(NSTRPX)=NT
               ISTRIPX(NSTRPX)=(J/2)+(LADD-1)*1024
               QSTRIPX(NSTRPX)=floatadcx
               XSTRIPX(NSTRPX)=GLOBSTRIPX(NP,NT,J)            
              ENDIF

            endif
        enddo
        

******************** Y side *************************

        c=cistry/cdec
        

        do j=1,nstripy

            jmen1=j-1
            jm1=1
            if(jmen1.lt.1) then
             jm1=0
             jmen1=1
            endif

            jmen2=j-2
            jm2=1
            if(jmen2.lt.1) then
             jm2=0
             jmen2=1
            endif

            jpiu1=j+1
            jp1=1
            if(jpiu1.gt.nstripy) then
             jp1=0
             jpiu1=nstripy
            endif

            jpiu2=j+2
            jp2=1
            if(jpiu2.gt.nstripy) then
             jp2=0
             jpiu2=nstripy
            endif

           stripqytanti(j)=proytanti(np,nt,j)*(1.-2.*c)+           
     +    c*(1.-2.*c)*(jm1*proytanti(np,nt,jmen1)+jp1*
     +    proytanti(np,nt,jpiu1))+
     +    (c**2)*(jm2*proytanti(np,nt,jmen2)+2.*proytanti(np,nt,j)+
     +    jp2*proytanti(np,nt,jpiu2))

           if(stripqytanti(j).gt.1.e-8) then


             IVA1=INT((J-1)/128)+1
             IF(badva1(NP*2-1,LADD,IVA1).EQ.1) THEN          

              NSTRPY=NSTRPY+1
              IF(NSTRPY.GT.MAXSTR) THEN
                WRITE(6,*) 'ERROR - NSTRPY > MAXSTR'
                NSTRPY=MAXSTR
              ENDIF
              floatadcy=stripqytanti(j)*ycalib
              NPSTRIPY(NSTRPY)=NP
              NTSTRIPY(NSTRPY)=NT
              ISTRIPY(NSTRPY)=J+(LADD-1)*1024
              QSTRIPY(NSTRPY)=FLOATADCY
              YSTRIPY(NSTRPY)=GLOBSTRIPY(NP,NT,J)
              
             ENDIF
             
            endif

         enddo

                
         END

1	*-- Author : Elena Taddei-Sergio Bottai 09/08/2005
2
3	SUBROUTINE GPUCOLLECTION(np,nt)
4
5	***************************************************************************
6	* *
7	* *
8	* *
9	* Here we calculate the signal appearing on each ADC channel *
10	* starting from the charge collected on every strip of the silicon *
11	* sensor. Noise is kept from data of beam test. Capacitive coupling *
12	* between strips and energy to ADC calibration are introduced too. *
13	* *
14	* *
15	* Called by: GPDSPE *
16	* *
17	***************************************************************************
18
19	#include "gpstripspe.inc"
20
21	c
22	c new strip capacitance simulation 19/02/09 S. Bottai
23	c
24	c
25	dimension stripqxtanti(nstripx)
26	dimension stripqytanti(nstripy)
27
28
29
30
31
32	******zeroing************
33
34	do i=1,nstripx
35	stripqxtanti(i)=0.
36	enddo
37	do i=1,nstripy
38	stripqytanti(i)=0.
39	enddo
40
41	***************************
42	if(NT.eq.1.or.NT.eq.4) LADD=1
43	if(NT.eq.2.or.NT.eq.5) LADD=2
44	if(NT.eq.3.or.NT.eq.6) LADD=3
45
46	*
47	* Odd strip, X side --> charge shared between adjacent strips
48	* EFFCOUPL --> coupling efficiency (capacitance to backplane =0?)
49	* SHIFTMASK --> asymmetry in charge division on X view
50	* different in each sensor (mask)
51
52
53	do j=(1+8),(nstripx-7),2
54	proxtanti(np,nt,j-1)=
55	+ proxtanti(np,nt,j-1)+
56	+ 0.5effcouplproxtanti(np,nt,j)*(1.-shiftmask)
57
58	proxtanti(np,nt,j+1)=
59	+ proxtanti(np,nt,j+1)+
60	+ 0.5effcouplproxtanti(np,nt,j)*(1.+shiftmask)
61	proxtanti(np,nt,j)=0.
62	enddo
63
64
65	*
66	* Capacitive coupling: a fraction of the charge arriving at one strip
67	* appears at the output of the neighbouring amplifiers
68	* This fraction is about Cis/Cdec, where Cis is the interstrip
69	* capacitance and Cdec is the decoupling capacitance (see Turchetta)
70	* An algorithm has been chosen that is precise for low values of the
71	* capacitive coupling, i.e. if the INDUCED charge on a given strip
72	* is little compared with the COLLECTED one.
73	*
74
75
76	****************** X side ***********************
77
78	c=cistrx/cdec
79	c2=cistrx2/cdec
80
81
82	do j=8,nstripx-6,2 ! only even strips on X side
83	CV jm2=1
84	CV IF(j-2.lt.8) jm2=0
85	CV jp2=1
86	CV IF(j+2.gt.(nstripx-6)) jp2=0
87	CV jm4=1
88	CV IF(j-4.lt.8) jm4=0
89	CV jp4=1
90	CV IF(j+4.gt.(nstripx-6)) jp4=0
91
92
93	stripqxtanti(j)=proxtanti(np,nt,j)
94	SUMF=0.
95	ccc DO KK=1,15
96	DO KK=1,4
97	KF=KK*2
98	IF(KK.EQ.1) FN=F1
99	IF(KK.EQ.2) FN=F2
100	IF(KK.EQ.3) FN=F3
101	IF(KK.EQ.4) FN=F4
102	IF(KK.GE.5) FN=F1/KK
103	IF((J-KF).GE.8) THEN
104	stripqxtanti(j)=stripqxtanti(j)+FN*proxtanti(np,nt,j-KF)
105	SUMF=SUMF+FN
106	ENDIF
107	IF((J+KF).LE.(nstripx-6)) THEN
108	stripqxtanti(j)=stripqxtanti(j)+FN*proxtanti(np,nt,j+KF)
109	SUMF=SUMF+FN
110	ENDIF
111	ENDDO
112
113	stripqxtanti(j)=stripqxtanti(j)-SUMF*proxtanti(np,nt,j)
114
115	cv stripqxtanti(j)=proxtanti(np,nt,j)(1.-2.(c+c2))+
116	cv + c(1.-2.c)(jm2proxtanti(np,nt,j-2)
117	cv + +jp2*proxtanti(np,nt,j+2))+
118	cv + (c*2)(jm4proxtanti(np,nt,j-4)(1.+c2/(c**2))+
119	cv + 2.proxtanti(np,nt,j)+jp4proxtanti(np,nt,j+4)(1.+c2/(c*2)))
120
121
122	if(stripqxtanti(j).gt.1.e-8) then
123
124	IVA1=INT((J/2-1)/128)+1
125	IF(badva1(NP*2,LADD,IVA1).EQ.1) THEN
126	NSTRPX=NSTRPX+1
127	floatadcx=stripqxtanti(j)*xcalib
128	IF(NSTRPX.GT.MAXSTR) THEN
129	WRITE(6,*) 'ERROR - NSTRPX > MAXSTR'
130	NSTRPX=MAXSTR
131	ENDIF
132	NPSTRIPX(NSTRPX)=NP
133	NTSTRIPX(NSTRPX)=NT
134	ISTRIPX(NSTRPX)=(J/2)+(LADD-1)*1024
135	QSTRIPX(NSTRPX)=floatadcx
136	XSTRIPX(NSTRPX)=GLOBSTRIPX(NP,NT,J)
137	ENDIF
138
139	endif
140	enddo
141
142
143	****************** Y side ***********************
144
145	c=cistry/cdec
146
147
148	do j=1,nstripy
149
150	jmen1=j-1
151	jm1=1
152	if(jmen1.lt.1) then
153	jm1=0
154	jmen1=1
155	endif
156
157	jmen2=j-2
158	jm2=1
159	if(jmen2.lt.1) then
160	jm2=0
161	jmen2=1
162	endif
163
164	jpiu1=j+1
165	jp1=1
166	if(jpiu1.gt.nstripy) then
167	jp1=0
168	jpiu1=nstripy
169	endif
170
171	jpiu2=j+2
172	jp2=1
173	if(jpiu2.gt.nstripy) then
174	jp2=0
175	jpiu2=nstripy
176	endif
177
178	stripqytanti(j)=proytanti(np,nt,j)(1.-2.c)+
179	+ c(1.-2.c)(jm1proytanti(np,nt,jmen1)+jp1*
180	+ proytanti(np,nt,jpiu1))+
181	+ (c*2)(jm2proytanti(np,nt,jmen2)+2.proytanti(np,nt,j)+
182	+ jp2*proytanti(np,nt,jpiu2))
183
184	if(stripqytanti(j).gt.1.e-8) then
185
186
187	IVA1=INT((J-1)/128)+1
188	IF(badva1(NP*2-1,LADD,IVA1).EQ.1) THEN
189
190	NSTRPY=NSTRPY+1
191	IF(NSTRPY.GT.MAXSTR) THEN
192	WRITE(6,*) 'ERROR - NSTRPY > MAXSTR'
193	NSTRPY=MAXSTR
194	ENDIF
195	floatadcy=stripqytanti(j)*ycalib
196	NPSTRIPY(NSTRPY)=NP
197	NTSTRIPY(NSTRPY)=NT
198	ISTRIPY(NSTRPY)=J+(LADD-1)*1024
199	QSTRIPY(NSTRPY)=FLOATADCY
200	YSTRIPY(NSTRPY)=GLOBSTRIPY(NP,NT,J)
201
202	ENDIF
203
204	endif
205
206	enddo
207
208
209	END
210