fChapter 5

1.Prepare a Context Diagram and Diagram 0 to meet the information system requirements as described in the case narrative.

Make sure they are balanced and that you meet all the diagramming rules outlined in the textbook (pp. 143 -160 in TR11) and lecture notes

2. Draw a logical flowchart (or modular design as the textbook refers to) for the vehicle and owner registration process.

Refer to the textbook (p. 166 in TR11) for the symbols to be used.

s.5 Guidelines for conest diagram wich a single process symbol. Next, the analyst creaiew a, which shows more detail. The analyst continues to create lower-levetel d of separate processes. Using leveling, an analyst starts with an overall FD unctions. More complex systems have more processes, and analvgle re exploding, partitioning, or decomposing. expl processes are identified as functional primitives, which represent s Leveling is also ing. the Figure S.13 and Figure S-14 provide an example of leveling, Figure s Now consider Figure S.14, which provides an exploded view of the FILL O ess. Noeice that FIL.L ORDER (process 1) actually consists of three ERIFY ORDER (process 1.1), PREPARE REJECT NOTICE (process t gram O for an order system, with the FILL ORDER process labele 13 pro 1.21, and ASSEMBLE ORDER (process 1.3). th ORDER REJECT ORDER STATUS ACCEPTED 02 PICKING DETAIL ASSEMBLE CHANGE FIGURE 5-14 Diagram I DFD shows details of the FILL ORDER process in the order system. As Figure 5-14 shows, all processes are numbered using a decimal notation con sisting of the parent's reference number, a decimal point, and a sequence number within the new diagram. In Figure 5-14, the parent process of diagram 1 is process so the processes in diagram 1 have reference numbers of 1.1, 1.2, and 1.3.I p 1.3, ASSEMBLE ORDER, is decomposed further, then it would appear in diagram and the processes in diagram 1.3 would be numbered as 1.3.1, 1.3.2, 1.3.3, and so on. This numbering technique makes it easy to integrate and identify all DFDs. s.5 Guidelines for conest diagram wich a single process symbol. Next, the analyst creaiew a, which shows more detail. The analyst continues to create lower-levetel d of separate processes. Using leveling, an analyst starts with an overall FD unctions. More complex systems have more processes, and analvgle re exploding, partitioning, or decomposing. expl processes are identified as functional primitives, which represent s Leveling is also ing. the Figure S.13 and Figure S-14 provide an example of leveling, Figure s Now consider Figure S.14, which provides an exploded view of the FILL O ess. Noeice that FIL.L ORDER (process 1) actually consists of three ERIFY ORDER (process 1.1), PREPARE REJECT NOTICE (process t gram O for an order system, with the FILL ORDER process labele 13 pro 1.21, and ASSEMBLE ORDER (process 1.3). th ORDER REJECT ORDER STATUS ACCEPTED 02 PICKING DETAIL ASSEMBLE CHANGE FIGURE 5-14 Diagram I DFD shows details of the FILL ORDER process in the order system. As Figure 5-14 shows, all processes are numbered using a decimal notation con sisting of the parent's reference number, a decimal point, and a sequence number within the new diagram. In Figure 5-14, the parent process of diagram 1 is process so the processes in diagram 1 have reference numbers of 1.1, 1.2, and 1.3.I p 1.3, ASSEMBLE ORDER, is decomposed further, then it would appear in diagram and the processes in diagram 1.3 would be numbered as 1.3.1, 1.3.2, 1.3.3, and so on. This numbering technique makes it easy to integrate and identify all DFDs. s.5 Guidelines for conest diagram wich a single process symbol. Next, the analyst creaiew a, which shows more detail. The analyst continues to create lower-levetel d of separate processes. Using leveling, an analyst starts with an overall FD unctions. More complex systems have more processes, and analvgle re exploding, partitioning, or decomposing. expl processes are identified as functional primitives, which represent s Leveling is also ing. the Figure S.13 and Figure S-14 provide an example of leveling, Figure s Now consider Figure S.14, which provides an exploded view of the FILL O ess. Noeice that FIL.L ORDER (process 1) actually consists of three ERIFY ORDER (process 1.1), PREPARE REJECT NOTICE (process t gram O for an order system, with the FILL ORDER process labele 13 pro 1.21, and ASSEMBLE ORDER (process 1.3). th ORDER REJECT ORDER STATUS ACCEPTED 02 PICKING DETAIL ASSEMBLE CHANGE FIGURE 5-14 Diagram I DFD shows details of the FILL ORDER process in the order system. As Figure 5-14 shows, all processes are numbered using a decimal notation con sisting of the parent's reference number, a decimal point, and a sequence number within the new diagram. In Figure 5-14, the parent process of diagram 1 is process so the processes in diagram 1 have reference numbers of 1.1, 1.2, and 1.3.I p 1.3, ASSEMBLE ORDER, is decomposed further, then it would appear in diagram and the processes in diagram 1.3 would be numbered as 1.3.1, 1.3.2, 1.3.3, and so on. This numbering technique makes it easy to integrate and identify all DFDs. s.5 Guidelines for conest diagram wich a single process symbol. Next, the analyst creaiew a, which shows more detail. The analyst continues to create lower-levetel d of separate processes. Using leveling, an analyst starts with an overall FD unctions. More complex systems have more processes, and analvgle re exploding, partitioning, or decomposing. expl processes are identified as functional primitives, which represent s Leveling is also ing. the Figure S.13 and Figure S-14 provide an example of leveling, Figure s Now consider Figure S.14, which provides an exploded view of the FILL O ess. Noeice that FIL.L ORDER (process 1) actually consists of three ERIFY ORDER (process 1.1), PREPARE REJECT NOTICE (process t gram O for an order system, with the FILL ORDER process labele 13 pro 1.21, and ASSEMBLE ORDER (process 1.3). th ORDER REJECT ORDER STATUS ACCEPTED 02 PICKING DETAIL ASSEMBLE CHANGE FIGURE 5-14 Diagram I DFD shows details of the FILL ORDER process in the order system. As Figure 5-14 shows, all processes are numbered using a decimal notation con sisting of the parent's reference number, a decimal point, and a sequence number within the new diagram. In Figure 5-14, the parent process of diagram 1 is process so the processes in diagram 1 have reference numbers of 1.1, 1.2, and 1.3.I p 1.3, ASSEMBLE ORDER, is decomposed further, then it would appear in diagram and the processes in diagram 1.3 would be numbered as 1.3.1, 1.3.2, 1.3.3, and so on. This numbering technique makes it easy to integrate and identify all DFDs