Abstract

The approach called as "graph theory and matrix approach" has been well employed in numerous research studies with a view to perform the decision-making while the situation is becoming perplexed type or where there is a very strong relative importance of one parameter over another. In such cases, the said graph theory and matrix method provides very suitable and fruitful solutions to make the decision to its final effective extent. The further improvements and the outcome enhancement can also be revealed through the use of combined practice of graph theory results along with some artificial intelligence-inspired logics and practices such as fuzzy logic, artificial neural network, etc. The significance and applicability of said method in vast fields of science, engineering, and research are also proved. Nowadays, our manufacturing sectors are getting up to date through the applications of artificial intelligence and several software-based directions. This is all to enhance the overall machine system performance with a view to improve desired performance characteristics of the process under the study. Few sections of this chapter has also elaborated the utility of the artificial intelligence-inspired fuzzy logic-based decision system which has already been a part of previous researches.

Keywords: diagraph, computer systems, artificial intelligence, matrix, industries, fuzzy logic, artificial neural network

## 1. Basic overview of graph theory

The decision-making has now been developed and practiced with the use of several recently emerged methodologies to make the traditionally employed practices more effective and impressive [1–3]. The behavior of humans has been mimicked out in an effective and limited way through artificial intelligence models. Artificial neural networks, evolutionary computing, fuzzy logic, probabilistic analysis models, intelligent agents, etc. are some major tools which usually define the basic artificial intelligence system. Wren and Jain [4] have explored the application of artificial intelligence (AI) while practicing a healthy decision-making in practical industry-based problems. There are so many AI techniques which have been investigated in past researches for the purpose of decision-making [5, 6]. These methodologies are, namely, data trend analyzing, coordinating the data delivery, forecast providing, data consistency development, uncertainty quantification, etc. The well-known decision-making method, called graph theory, is a systematic and

logical approach which also has proven to be useful for analyzing and modeling a wide range of applications in engineering and numerous other areas. This methodology is particularly based on the advanced theory of graphs, and therefore its applications are very well renowned. The demonstration through graph "or" digraph model has proven to be useful for modeling and analyzing numerous varieties of systems and problems in numerous fields of science and technology [7–9]. The approach based on the matrix method is useful in analyzing the graph/digraph models expeditiously to derive the system function and index to meet the objectives.

Graph theory is a subject of combinatorial mathematics and draws a lot from matrix theory. The matrix representation of the graph molds the problem to make use of computers for various complex operations. The graph theory and matrix methods (GTMM) consist of the digraph representation, the matrix representation, and the mathematical representation, i.e., a permanent function. The digraph is the visual representation of the variables and their interdependencies. The matrix converts the digraph into mathematical form, and the permanent function is a mathematical representation that helps to determine the numerical index [10, 11]. The graph theory approach is a systematic approach for conversion of qualitative factors to quantitative values, and mathematical modeling gives an edge to the proposed technique over conventional methods like cause-effect diagrams, flow charts, etc. These method outcomes can now be settled into some artificial intelligence-based tools and steps to generate some more fruitful and smart solutions. More specifically, the fuzzy logic-based approach can be implemented further to utilize the human thoughts regarding the problem under consideration. The logic generation will be based on the pure human experiences which help to implement the artificial intelligence-based graph theory approach more reasonable and practicable. The AI, generally described as the discipline of developing machines performing things that would entail human astuteness, is often perplexed with robotics, particularly humanoid robotics, as they are contiguous to "human" intellect. Graph theory has a wide range of applications in engineering and numerous other areas. The essential steps for executing the abovesaid methodology are as follows.

#### 2. Selection of attributes

In this chief step, various characteristics which affect the outcome under study are identified, and the experimental design that gratifies the operation requirements is finalized. The trait values (Ti) and relative importance (uij) are obtained using Tables 1 and 2.

2.2 Matrix representation of the machinability attribute digraph

S. no. Qualitative measure of factors affecting

DOI: http://dx.doi.org/10.5772/intechopen.82011

Quantification of factors affecting machinability of titanium [12].

Relative importance of machinability attributes (uij) [12].

machinability of titanium

1. Exceptionally low 0 2. Extremely low 1 3. Very low 2 4. Below average 3 5. Average 4 6. Above average 5 7. Moderate 6 8. High 7 9. Very high 8 10. Extremely high 9 11. Exceptionally high 10

Decision-Making in Real-Life Industrial Environment through Graph Theory Approach

Assigned value of machinability factors (Ti)

uij uji = 10-uij

diagonal elements of the matrix for individual attributes [12, 13].

estimation digraph (Figure 1).

Table 1.

Table 2.

121

The digraph is needed to be characterized in matrix form (H) called a variable

The tradition of the three imperative attributes is embodied by diagonal elements T1, T2, and T3, and interdependencies between them are revealed by off-

For the deliberated machinability attribute digraph, the matrix H is illustrated as

ð1Þ

permanent matrix for permanent machinability index (VPMM). This is X � X matrix which deliberates all of the attributes (i.e.,Ti) with their relative importance (i.e., uij). The matrix shown in Eq. (1) is articulated as per the machinability

S. no. Category description Interdependencies of attributes

1. Two attributes are of equal importance 5 5 2. One attribute is slightly more important than the other 6 4 3. One attribute is more important than the other 7 3 4. One attribute is much more important than the other 8 2 5. One attribute is extremely more important than the other 9 1 6. One attribute is exceptionally more important than the other 10 0

#### 2.1 Machinability attribute digraph representation

A digraph is exploited to illustrate the aspects which affect the machinability and interdependencies among them in terms of edges and nodes. A cluster of directed edges R = {uij} and a cluster of nodes Q = {Ti}, with i ¼ 1, 2, …, X, consist in a digraph. A node Ti signifies the ith machinability attribute, and edges epitomize their relative importance. The number of nodes (X) reflected is the same as the number of machinability attributes considered for the machining operation. For example, three vital attributes, viz., material removal rate (1), tool wear rate (2), and surface roughness (3), are designated for the assessment of machinability work considered. The machinability characteristic diagraph is represented as shown in Figure 1.


Decision-Making in Real-Life Industrial Environment through Graph Theory Approach DOI: http://dx.doi.org/10.5772/intechopen.82011

#### Table 1.

logical approach which also has proven to be useful for analyzing and modeling a

methodology is particularly based on the advanced theory of graphs, and therefore its applications are very well renowned. The demonstration through graph "or" digraph model has proven to be useful for modeling and analyzing numerous varieties of systems and problems in numerous fields of science and technology [7–9]. The approach based on the matrix method is useful in analyzing the graph/digraph models expeditiously to derive the system function and index to

Graph theory is a subject of combinatorial mathematics and draws a lot from matrix theory. The matrix representation of the graph molds the problem to make use of computers for various complex operations. The graph theory and matrix methods (GTMM) consist of the digraph representation, the matrix representation, and the mathematical representation, i.e., a permanent function. The digraph is the visual representation of the variables and their interdependencies. The matrix converts the digraph into mathematical form, and the permanent function is a mathematical representation that helps to determine the numerical index [10, 11]. The graph theory approach is a systematic approach for conversion of qualitative factors to quantitative values, and mathematical modeling gives an edge to the proposed technique over conventional methods like cause-effect diagrams, flow charts, etc. These method outcomes can now be settled into some artificial intelligence-based tools and steps to generate some more fruitful and smart solutions. More specifically, the fuzzy logic-based approach can be implemented further to utilize the human thoughts regarding the problem under consideration. The logic generation will be based on the pure human experiences which help to implement the artificial intelligence-based graph theory approach more reasonable and practi-

cable. The AI, generally described as the discipline of developing machines performing things that would entail human astuteness, is often perplexed with robotics, particularly humanoid robotics, as they are contiguous to "human" intellect. Graph theory has a wide range of applications in engineering and numerous other areas. The essential steps for executing the abovesaid methodology are as

In this chief step, various characteristics which affect the outcome under study are identified, and the experimental design that gratifies the operation requirements is finalized. The trait values (Ti) and relative importance (uij) are obtained using

A digraph is exploited to illustrate the aspects which affect the machinability and interdependencies among them in terms of edges and nodes. A cluster of directed edges R = {uij} and a cluster of nodes Q = {Ti}, with i ¼ 1, 2, …, X, consist in a digraph. A node Ti signifies the ith machinability attribute, and edges epitomize their relative importance. The number of nodes (X) reflected is the same as the number of machinability attributes considered for the machining operation. For example, three vital attributes, viz., material removal rate (1), tool wear rate (2), and surface roughness (3), are designated for the assessment of machinability work considered. The machinability characteristic diagraph is represented as shown in

wide range of applications in engineering and numerous other areas. This

Computer Architecture in Industrial, Biomechanical and Biomedical Engineering

meet the objectives.

follows.

Tables 1 and 2.

Figure 1.

120

2. Selection of attributes

2.1 Machinability attribute digraph representation

Quantification of factors affecting machinability of titanium [12].


Table 2.

Relative importance of machinability attributes (uij) [12].

#### 2.2 Matrix representation of the machinability attribute digraph

The digraph is needed to be characterized in matrix form (H) called a variable permanent matrix for permanent machinability index (VPMM). This is X � X matrix which deliberates all of the attributes (i.e.,Ti) with their relative importance (i.e., uij). The matrix shown in Eq. (1) is articulated as per the machinability estimation digraph (Figure 1).

The tradition of the three imperative attributes is embodied by diagonal elements T1, T2, and T3, and interdependencies between them are revealed by offdiagonal elements of the matrix for individual attributes [12, 13].

For the deliberated machinability attribute digraph, the matrix H is illustrated as

$$\begin{array}{c|c|c|c|c|c|c} \text{Attribute} & \mathbf{1}\_{1} & \mathbf{2} & \mathbf{3} & \mathbf{4} & \text{non-convex} \\ \mathbf{1} & \mathbf{T}\_{1} & \mathbf{u}\_{12} & \mathbf{u}\_{13} & \mathbf{u}\_{14} & \dots & \mathbf{u}\_{18} & \mathbf{u}\_{19} \\ \mathbf{2} & \mathbf{u}\_{21} & \mathbf{T}\_{2} & \mathbf{u}\_{23} & \mathbf{u}\_{24} & \dots & \mathbf{u}\_{29} \\ \mathbf{3} & \mathbf{u}\_{31} & \mathbf{u}\_{32} & \mathbf{T}\_{3} & \mathbf{u}\_{34} & \dots & \mathbf{u}\_{39} \\ \mathbf{4} & \mathbf{u}\_{41} & \mathbf{u}\_{42} & \mathbf{u}\_{43} & \mathbf{T}\_{4} & \dots & \mathbf{u}\_{48} \\ & \mathbf{5} & \mathbf{6} & \mathbf{7} & \mathbf{8} & \mathbf{8} & \mathbf{9} & \mathbf{1} \\ & \mathbf{8} & \mathbf{8} & \mathbf{9} & \mathbf{1} & \mathbf{3} & \mathbf{1} & \mathbf{2} \\ & & \mathbf{8} & \mathbf{1} & \mathbf{4} & \mathbf{1} & \mathbf{5} & \mathbf{2} \\ & & & \mathbf{8} & \mathbf{1} & \mathbf{6} & \mathbf{1} & \mathbf{8} \end{array} \tag{1}$$

#### Figure 1. Machinability attribute digraph representation.

Representation of this variable permanent matrix for VPMM for the considered machinability attribute digraph (shown in Figure 1) is given below:


All the assessable values of Ti are needed to be normalized on the similar scale as qualitative values, i.e., 0 to 10. For beneficial machinability attributes, the obligation of 0 and 10 is for smaller range value (Tis) and bigger range value (Tib), respectively. Other midway values Tii of the traits could also be dispensed in the scale

For non-beneficial machinability attributes, assignment of 0 and 10 is for bigger range value (Tis) and smaller range value (Tib), respectively. Other intermediate values Tii of the attributes could also be assigned in the scale from 0 to 10, as shown

Relative interdependency amid two traits (i.e., uij) for the considered project is also allotted as a value over the range from 0 to 10 and is arranged into six categories. The interdependency between two attributes can be distributed on the scale

The investigational runs are then arranged in down/rising order as per the calculated values of permanent machinability index. The investigational run having the highest value of permanent machinability index is chosen as the best alternative

Let Vij signify the total assessment of the terms of jth sub-clustering of the ith clustering of the variable permanent machinability function. For the case of no subgrouping, then the situation will be Vij = Vi, i.e., total assessment of terms of the ith

=V1=V2=V3=V4=V<sup>51</sup> þ V52=V<sup>61</sup> þ V62= (7)

Cd ¼ ð Þ 1=B ∑Φij, i, j (8)

Cs ¼ 1 � Cd (9)

2.5 Identification and comparison of different available alternatives

clustering. The identification set for an experimental run for the considered

(Cd) for any two investigational runs is proposed as

where B = max. of [∑ |Vij| and ∑ |V'ij|], i,j i,j

Φij = |Vij - V'ij |. The similarity coefficient is also expressed as

A contrast between any two investigational runs can also be made by using Eq. (8). On the basis of divergence of performance, the dissimilarity coefficient

The assessments of the terms for the variable permanent machinability function (Vij and V'ij) for two investigational run under the estimation and contrast, and

Ti <sup>¼</sup> f g <sup>10</sup>=ð Þ Tib � Tis � ð Þ Tii � Tis for Tis>0 (4)

Ti <sup>¼</sup> f g <sup>10</sup>=ð Þ Tib � Tis � ð Þ Tib � Tii for Tis>0 (5)

uij ¼ 10 � uji (6)

Ti ¼ f g� 10=Tib Tii for Tis ¼ 0

Decision-Making in Real-Life Industrial Environment through Graph Theory Approach

Ti ¼ 10 1 f g � ð Þ Tii=Tib for Tis ¼ 0

from 0 to 10, as in Eq. (4):

DOI: http://dx.doi.org/10.5772/intechopen.82011

in Eq. (5):

0 to 10 as given below:

machining process is

123

for the task under deliberation.

#### 2.3 Variable permanent function representation

The permanent of this matrix H, i.e., per (H), is distinct as the permanent machinability function. Machinability estimation signifies machinability traits of various experimental runs as measured. Furthermore, this tactic leads to avoid any loss of data as it does not carry any negative sign in the expression [12].

The "variable permanent machinability function" is expressed in sigma form as

x per Hð Þ¼ <sup>Y</sup> i¼1 Ti <sup>þ</sup> <sup>∑</sup>i,j,…,<sup>X</sup> uijuji � � TkTl…TX <sup>þ</sup> <sup>∑</sup>i,j,…<sup>X</sup> uijujkuki <sup>þ</sup> uikukjuji � �TlTm…TX <sup>þ</sup> <sup>∑</sup>i,j,…<sup>X</sup> uijuji � �ð Þ uklulk TmTn…TX <sup>þ</sup> <sup>∑</sup> <sup>i</sup>,j, …<sup>X</sup> uijujkukluli <sup>þ</sup> uilulkukjuji � � TmTn…TX ( ) <sup>þ</sup> <sup>∑</sup>i,j,…:Xð Þ ulmuml uijujkuki <sup>þ</sup> uikukjuji � �TnTo…TX <sup>þ</sup> <sup>∑</sup>i,j,…<sup>X</sup> uijujkuklulmumi <sup>þ</sup> uimumlulkukjuji � �TnTo…TX� h i þ½ð∑i,j,…:Xð Þ umnunm uijujkukluli <sup>þ</sup> uilulkukjuji � �To…TX <sup>þ</sup> <sup>∑</sup>i,j,…<sup>X</sup> uijujkuki <sup>þ</sup> uikukjuji � � <sup>ð</sup>ulmumnunl<sup>þ</sup> ulnunmuml<sup>Þ</sup> To:…TX <sup>þ</sup> <sup>∑</sup>i,j,…:<sup>X</sup> uijuji � �ð Þ uklulk ð Þ umnunm To…TX <sup>þ</sup>∑i,j,…:<sup>X</sup> uijujkuklulmumnuni <sup>þ</sup> uinunmumlulkukjuji � � To…TX<sup>Þ</sup> (3)

#### 2.4 Evaluation of permanent machinability index

The permanent machinability function defined in Eq. (3) is engaged for appraisal of the permanent machinability index. The permanent machinability index is articulated as the arithmetical value of permanent machinability function.

Decision-Making in Real-Life Industrial Environment through Graph Theory Approach DOI: http://dx.doi.org/10.5772/intechopen.82011

All the assessable values of Ti are needed to be normalized on the similar scale as qualitative values, i.e., 0 to 10. For beneficial machinability attributes, the obligation of 0 and 10 is for smaller range value (Tis) and bigger range value (Tib), respectively. Other midway values Tii of the traits could also be dispensed in the scale from 0 to 10, as in Eq. (4):

$$\begin{aligned} \mathbf{T\_i} &= \{\mathbf{10}/\mathbf{T\_{ib}}\} \times \mathbf{T\_{ii}} \quad \text{for } \mathbf{T\_{is}} = \mathbf{0} \\ \mathbf{T\_i} &= \{\mathbf{10}/(\mathbf{T\_{ib}} - \mathbf{T\_{is}})\} \times (\mathbf{T\_{ii}} - \mathbf{T\_{is}}) \quad \text{for } \mathbf{T\_{is}} > \mathbf{0} \end{aligned} \tag{4}$$

For non-beneficial machinability attributes, assignment of 0 and 10 is for bigger range value (Tis) and smaller range value (Tib), respectively. Other intermediate values Tii of the attributes could also be assigned in the scale from 0 to 10, as shown in Eq. (5):

$$\begin{aligned} \mathbf{T\_i} &= \mathbf{10} \{ \mathbf{1} - (\mathbf{T\_{ii}}/\mathbf{T\_{ib}}) \} \text{ for } \mathbf{T\_{is}} = \mathbf{0} \\ \mathbf{T\_i} &= \{ \mathbf{10} / (\mathbf{T\_{ib}} - \mathbf{T\_{is}}) \} \times (\mathbf{T\_{ib}} - \mathbf{T\_{ii}}) \text{ for } \mathbf{T\_{is}} > \mathbf{0} \end{aligned} \tag{5}$$

Relative interdependency amid two traits (i.e., uij) for the considered project is also allotted as a value over the range from 0 to 10 and is arranged into six categories. The interdependency between two attributes can be distributed on the scale 0 to 10 as given below:

$$\mathbf{u}\_{\text{i}\dagger} = \mathbf{10} - \mathbf{u}\_{\text{ji}} \tag{6}$$

The investigational runs are then arranged in down/rising order as per the calculated values of permanent machinability index. The investigational run having the highest value of permanent machinability index is chosen as the best alternative for the task under deliberation.

#### 2.5 Identification and comparison of different available alternatives

Let Vij signify the total assessment of the terms of jth sub-clustering of the ith clustering of the variable permanent machinability function. For the case of no subgrouping, then the situation will be Vij = Vi, i.e., total assessment of terms of the ith clustering. The identification set for an experimental run for the considered machining process is

$$\left(\mathbf{V\_1/V\_2/V\_3/V\_4/V\_{51}} + \mathbf{V\_{52}/V\_{61}} + \mathbf{V\_{62}/}\right) \tag{7}$$

A contrast between any two investigational runs can also be made by using Eq. (8). On the basis of divergence of performance, the dissimilarity coefficient (Cd) for any two investigational runs is proposed as

$$\mathbf{C\_d} = (\mathbf{1}/\mathbf{B}) \sum \Phi\_{\mathbf{i}\flat} \text{ i, j} \tag{8}$$

where B = max. of [∑ |Vij| and ∑ |V'ij|], i,j i,j

The assessments of the terms for the variable permanent machinability function (Vij and V'ij) for two investigational run under the estimation and contrast, and Φij = |Vij - V'ij |. The similarity coefficient is also expressed as

$$\mathbf{C}\_{\mathbf{s}} = \mathbf{1} - \mathbf{C}\_{\mathbf{d}} \tag{9}$$

Representation of this variable permanent matrix for VPMM for the considered

The permanent of this matrix H, i.e., per (H), is distinct as the permanent machinability function. Machinability estimation signifies machinability traits of various experimental runs as measured. Furthermore, this tactic leads to avoid any loss of data as it does not carry any negative sign in the expression [12].

� � TkTl…TX <sup>þ</sup> <sup>∑</sup>i,j,…<sup>X</sup> uijujkuki <sup>þ</sup> uikukjuji

<sup>i</sup>,j, …<sup>X</sup>

� �ð Þ uklulk ð Þ umnunm To…TX

The permanent machinability function defined in Eq. (3) is engaged for appraisal of the permanent machinability index. The permanent machinability index is articulated as the arithmetical value of permanent machinability function.

( )

The "variable permanent machinability function" is expressed in sigma form as

� �TlTm…TX

� �TnTo…TX�

� � <sup>ð</sup>ulmumnunl<sup>þ</sup>

uijujkukluli þ uilulkukjuji � � TmTn…TX

� �TnTo…TX <sup>þ</sup> <sup>∑</sup>i,j,…<sup>X</sup> uijujkuklulmumi <sup>þ</sup> uimumlulkukjuji

h i

� �To…TX <sup>þ</sup> <sup>∑</sup>i,j,…<sup>X</sup> uijujkuki <sup>þ</sup> uikukjuji

ð2Þ

(3)

machinability attribute digraph (shown in Figure 1) is given below:

Computer Architecture in Industrial, Biomechanical and Biomedical Engineering

2.3 Variable permanent function representation

� �ð Þ uklulk TmTn…TX <sup>þ</sup> <sup>∑</sup>

þ ∑i,j,…:Xð Þ ulmuml uijujkuki þ uikukjuji

ulnunmumlÞ To:…TX þ ∑i,j,…:<sup>X</sup> uijuji

þ½ð∑i,j,…:Xð Þ umnunm uijujkukluli þ uilulkukjuji

þ∑i,j,…:<sup>X</sup> uijujkuklulmumnuni þ uinunmumlulkukjuji

2.4 Evaluation of permanent machinability index

� � To…TX<sup>Þ</sup>

x per Hð Þ¼ <sup>Y</sup>

122

Figure 1.

i¼1

þ ∑i,j,…<sup>X</sup> uijuji

Ti þ ∑i,j,…,<sup>X</sup> uijuji

Machinability attribute digraph representation.

#### 2.6 Coefficients of similarity and dissimilarity

The calculation is being performed for similarity and dissimilarity coefficients as per Eqs. (8) and (9).

can also be provided perfectly by properly understanding and practicing the modeling and simulation methodologies related to the artificial intelligence. Furthermore, the decision support system also helps to gather, analyze, and trend forming of the existing demands of the customer or end product user [16, 17].

Decision-Making in Real-Life Industrial Environment through Graph Theory Approach

Rao and Gandhi [8, 9] have analyzed the failure reasons of a machine tool by means of digraph and matrix approaches. The machine tool failure causation digraph has been modeled a failure reason taking into deliberation its failurebacking actions and their contact in terms of the reason—consequence relationship. After that, they have determined machine tool failure causation function from the machine tool failure causation matrix. The said matrix was attained through the digraph, which is distinctive of the failure root. The obtained function was not only convenient for failure reason analysis but likewise for comparison and appraisal of the failure reason. In addition, the machine tool failure causality index, derived from the machine tool failure causality function, had also been proposed, which

The attained machine tool failure causation function has identified the backing failure occasions of a machine tool that were decisive for minimization of the failure root and also supports in contrast and assessment of the failure source of a machine tool. The arithmetical value of the machine tool failure causation function has also been computed and named as the machine tool failure cause index. This index has been concluded as a measure of the severity of the failure cause. Furthermore, an artificial intelligence-inspired fuzzy logic-based system can properly help to make the problem more realistic, and the causes of the tool failures can be resolved out or eliminated [18, 19]. The AI-based process optimization is another domain where the failure reduction and the overall performance improvement can be settled out.

Rao and Padmanabhan [20] have employed a graph theory-based methodology for selection of a rapid prototyping (RP) process that best suits the end use of a given product or part. The "rapid prototyping process selection index" has been also anticipated to estimate and rank the RP progressions for constructing a given product. The index was gained from an RP procedure assortment attribute function, acquired from the RP course selection attribute digraph. The digraph is established considering RP method assortment attributes and their relative importance for the deliberated application. The projected process reflects RP process variety attributes and their interrelations, and the RP process assortment index evaluates and ranks RP processes for a given RP procedure collection problem. The projected method was observed as a broad technique and capable to deliberate any number of measurable and qualitative RP course assortment attributes concurrently and proposes a

3.3 Failure cause analysis of machine tools

DOI: http://dx.doi.org/10.5772/intechopen.82011

evaluated and ranked the failure causes of a machine tool.

more objective and modest RP method selection approach.

3.5 Performance evaluation of carbide compacting die

125

Jangra et al. [21, 22] conducted a study to assess the concert of carbide compacting die by means of graph theory approach (GTA). Factors influencing the die performance and their relations were analyzed by evolving a mathematical model by employing the digraph-based matrix method. The die performance index was attained through the matrix model established from the developed digraphs.

This index value has compared and ranked the factors distressing the die

3.4 Selection of rapid prototyping process

### 3. Case studies on graph theory: a view on real-life problem solving

There are so many investigations that have been carried out by the numerous researchers throughout the globe in the domain of graph theory and its allied approaches to study and analyze the method's applicability and reliability. The further optimization of the process under the study can also help the investigator to attain better and effective research outcomes [1, 14]. The discussion has also been explored by incorporating the possibilities to use the artificial intelligence-inspired logics in collaboration with the established graph theory approach. In this way, some case studies are reviewed and presented below to provide an overview which can explore about the major findings of the researches persuaded and the stateof-the-art representation of past investigations in the best conclusive manner. The selected case studies are as follows.

#### 3.1 Machinability evaluation of work materials

Rao and Gandhi [8, 9] have presented a graph theory-based methodology with a view to evaluate the machinability of work materials for a given machining operation. They have proposed a universal machinability index that evaluates and ranks work materials for a given machining operation. The development of a digraph was also conducted to reflect the machinability attributes and their relative importance for the operation considered. The coefficients of similarity and dissimilarity and the identification sets have also been proposed. Disparate the traditional methods which adopt only one of the machinability assessment criteria, their proposed method has considered all of the criteria simultaneously and gives the correct and complete evaluation of the machinability of work materials. They have concluded that their proposed universal machinability index evaluates and ranks work materials for the considered machining operation. When it comes to taking the combined advantages of the features of artificial intelligence with the graph theory approach, the process moderation always becomes more crucial to consider. The requirements of the end customer regarding the produced goods further become extensively vital.

#### 3.2 Selection of industrial robot

Rao and Padmanabhan [15] have conducted a research study based on graph theory method for the evaluation of alternative industrial robots. They have attained a robot selection index that evaluates and ranks robots for a considered industrial application. The calculated index was obtained from a robot selection attribute function, obtained from the robot selection attribute digraph. They have reported that the obtained similarity index from robot selection attribute function which was quite useful for easy storage and retrieval of the data. The proposed study was a general methodology, and there can be any number of quantitative and qualitative robot selection attributes simultaneously and offers a more objective, simple, and consistent robot selection approach. Their proposed robot selection index has been utilized to evaluate and rank the robots for the selected robot selection problem. In addition, the expectation of the end user of the robotic system

#### Decision-Making in Real-Life Industrial Environment through Graph Theory Approach DOI: http://dx.doi.org/10.5772/intechopen.82011

can also be provided perfectly by properly understanding and practicing the modeling and simulation methodologies related to the artificial intelligence. Furthermore, the decision support system also helps to gather, analyze, and trend forming of the existing demands of the customer or end product user [16, 17].
