Pulse Processing; Figure 6, Block Circuit Diagram Of Impulse Processing - Baer DLX User Manual

3.5

Pulse processing

All impulses or analogues values at the inputs will be counted after de-
bouncing and then processed according the table below.
Energy
Pulse inputs
Input 1..16
Energy registers cumulative
In1 to In16
total
X
In1
Pulses
100-ee
Y
In1
Momentary current
value
Energy registers for current
total
X
In16
250-ee
Y
In16
current
Energy total
1 ... 4
+1
0
-1
+1
0
-1
Demand /
Increment
Input 1..16
Registration period MP1
60
MP1
Registration period MP2
60
MP2

Figure 6, Block circuit diagram of impulse processing

A calculation of values for registration period Tm2/MP2 only takes
place if the parameter is set under the menu item „Registration pe-
riod" in DLXPARA.
101-ee 191-ee
102-ee 192-ee
190-ee
103-ee 193-ee
last MP1
AT
104-ee 194-ee
current last MP1
251-ee 221-ee
252-ee 222-ee
220-ee
253-ee 223-ee
last MP1
254-ee 224-ee
AT
current last MP1
Hysteresis: 29300-pp
1
REG{120-nn} = ( ( ( (
REG{270-nn} = ( ( ( (
Maximum demand
300-ee
301-ee
131-ee 161-ee 302-ee
current last MP1 303-ee
MT
304-ee
Value + Time
Demand /
Increment
Total 1..4
+1
0
-1
Balance: 31000-04
+1
0
-1
REG{132-ee} = {DIFF
MP2
132-ee 162-ee
REG{132-ee} = {DIFF
MP2
current last MP2
+1
0
-1
Balance: 31000-04
+1
0
-1
The following registers {REG} are used for results : (see Appendix B)
For register addresses the following sub-addresses are possible:
ee = 01..16 Inputs 1..16
pp = 01..04 Total forwards 1..4 (positive)
nn = 01..04 Total backwards 1..4 (negative)
rate 1
rate 2
× × × × REG{30000-ee} ⁄ ⁄ ⁄ ⁄ REG{30100-ee}
REG{100-ee} = IE
rate 3
ee
rate 4
rate 1
× × × × REG{30000-ee} ⁄ ⁄ ⁄ ⁄ REG{30100-ee}
REG{250-ee} = IE
rate 2 ee
rate 3
rate 4
Σ Σ Σ Σ ±
REG{110-pp} = ( ( ( ( REG{100-ee} ) ) ) ) cumulative
Σ Σ Σ Σ ±
REG{260-pp} = ( ( ( ( REG{100-ee} ) ) ) ) current
1
29200-pp
111-pp
112-pp
110-pp 200-pp
113-pp
current last MP1
114-pp
AT
current
261-pp
262-pp
260-pp 230-pp
263-pp
current last MP1
AT 264-pp
current
29200-pp 121-nn
122-nn
120-nn 210-nn 123-nn
current last MP1
124-nn
AT
current
271-pp
272-pp
270-nn 240-nn
273-pp
current last MP1
AT
274-pp
Σ Σ Σ Σ ±
REG{100-ee} ) ) ) ) cum.
current
Σ Σ Σ Σ ±
REG{100-ee} ) ) ) ) curr.
Total
rate 1
} REG{100-ee} × × × × 60 ⁄ ⁄ ⁄ ⁄ MP1
REG{131-ee} = {DIFF
rate 2
MP1
REG{131-ee} = {DIFF } REG{100-ee}
rate 3
MP1
rate 4
Σ Σ Σ Σ ±
REG{141-pp} = ( ( ( ( REG{131-ee} ) ) ) )
141-pp 171-pp
current last MP1
MT
151-nn 181-nn
current last MP1
MT
Σ Σ Σ Σ ±
REG{151-nn} = ( ( ( ( REG{131-ee} ) ) ) )
} REG{100-ee} × × × × 60 ⁄ ⁄ ⁄ ⁄ MP2
for demand
} REG{100-ee} for increment
Σ Σ Σ Σ ±
REG{142-pp} = ( ( ( ( REG{132-ee} ) ) ) )
142-pp 172-pp
current last MP2
152-nn 182-nn
current last MP2
Σ Σ Σ Σ ±
REG{152-nn} = ( ( ( ( REG{132-ee} ) ) ) )
Pulses IA +
pp
201-pp rate 1
Momentary
202-pp rate 2
value
203-pp rate 3
204-pp rate 4
Forward
last MP1
231-pp rate 1
rate 2
232-pp
rate 3
233-pp
rate 4
234-pp
last MP1
Pulses IA -
nn
211-nn rate 1
Momentary
212-nn rate 2
value
213-nn rate 3
rate 4
214-nn
last MP1
Backward
241-pp rate 1
242-pp rate 2
rate 3
243-pp
rate 4
244-pp
last MP1
for demand
for increment
Maxima
310-pp
Total
311-pp
rate 1
Forward
312-pp rate 2
313-pp rate 3
314-pp rate 4
Value + Time
Maxima
320-nn Total
rate 1
321-nn
rate 2
322-nn Backward
rate 3
323-nn
rate 4
324-nn
Value + Time
19