A Novel Framework of q-Rung Orthopair Fuzzy Sets in Field

Alnefaie, Kholood; Xin, Qin; Almutlg, Ahmad; Abo-Tabl, El-Sayed A.; Mateen, M. Haris

doi:10.3390/sym15010114

Open AccessArticle

A Novel Framework of q-Rung Orthopair Fuzzy Sets in Field

by

Kholood Alnefaie

¹

,

Qin Xin

²

,

Ahmad Almutlg

³

,

El-Sayed A. Abo-Tabl

^3,4

and

M. Haris Mateen

^5,*

¹

Department of Mathematics, College of Science, Taibah University, Madinah 42353, Saudi Arabia

²

Faculty of Science and Technology, University of the Faroe Islands, FO 100 Torshavn, Faroe Islands, Denmark

³

Department of Mathematics, College of Science and Arts, Methnab, Qassim University, Buraidah 51931, Saudi Arabia

⁴

Department of Mathematics, Faculty of Science, Assiut University, Assiut 71516, Egypt

⁵

School of Mathematics, Minhaj University, Lahore 54000, Pakistan

^*

Author to whom correspondence should be addressed.

Symmetry 2023, 15(1), 114; https://doi.org/10.3390/sym15010114

Submission received: 4 December 2022 / Revised: 18 December 2022 / Accepted: 26 December 2022 / Published: 31 December 2022

(This article belongs to the Special Issue Algorithms for Multi-Criteria Decision-Making under Uncertainty)

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Abstract

:

In this manuscript, we proposed a novel framework of the q-rung orthopair fuzzy subfield (q-ROFSF) and illustrate that every Pythagorean fuzzy subfield is a q-rung orthopair fuzzy subfield of a certain field. We extend this theory and discuss its diverse basic algebraic characteristics in detail. Furthermore, we prove some fundamental results and establish helpful examples related to them. Moreover, we present the homomorphic images and pre-images of the q-rung orthopair fuzzy subfield (q-ROFSF) under field homomorphism. We provide a novel ideology of a non-standard fuzzy subfield in the extension of the q-rung orthopair fuzzy subfield (q-ROFSF).

Keywords:

q-rung orthopair fuzzy set; q-rung orthopair fuzzy subfield; q-rung orthopair fuzzy homomorphism subfield

1. Introduction

The fuzzy subring was introduced by Bhakat [1], and many other mathematicians have devoted a lot of time to studying fuzzy subsystems of various algebraic structures. Group theory, ring theory, field theory, modules, vector spaces, lattices, and algebras over a field are example applications of algebraic structures. In abstract algebra, a field is a very beneficial part that takes different algebraic structures on them. It is a branch of modern algebra that has come to the forefront many years ago. A very useful area of mathematics, called field theory, has been employed extensively in cryptography, coding theory, combinatorial mathematics, cyber security, and the study of electronics circuits. McEliece [2] introduced finite fields in computer and engineering studies. He discussed algebraic coding theory mathematically based on the theory of finite fields. He also treated coding theory courses in “Volkswagen” using finite fields in detail.

The fuzzy set theory is based on the principle of related rank-based affiliation, which is based on subjective experience and thinking. In 1965, Zadeh [3] established fuzzy set and its fundamental algebraic results. The use of fuzzy set theory provides a powerful framework for addressing ambiguity and uncertainty in practical issues. As a result, crisp sets frequently lack the appropriate response and feedback for real-world situations with growing problems. A fuzzy subset

E

of a classical set

W

is define as

{w, ρ_{E} (w) : w \in W}

; thus,

ρ_{E} : W : \to [0, 1]

is known as a supporting degree. By widening the function’s range from {0, 1} to [0, 1], it is undeniable that fuzzy sets are modifications of the characteristics value of traditional sets. Many scholars in various fields of agricultural science, mathematics, environmental science, and space science find fuzzy theory to be an attractive and engaging topic because a variety of fields, including coding theory, journey time histories, protein structure analysis, and medical diagnostic methods, adopt this special theory. Rosenfeld [4] 1971 gave the novel concept of a fuzzy subgroup with a basic fundamental algebraic structure. Liu [5] connected ring theory and fuzzy sets and established the notion of a fuzzy subring. Atanassov [6] invented the theory of intuitionistic fuzzy sets and also provided the basic algebraic characteristics of this phenomenon. This concept has improved in effectiveness in the scientific community because it focuses on the degree of participation and non-participation within a unit interval; therefore,

ρ_{E} : W : \to [0, 1]

represent the belonging degree and

{\bar{ρ}}_{E} : W : \to [0, 1]

represent the not belonging degree. This tenet is obviously a fundamental aspect of traditional fuzzy sets since it gives people more chances to present inaccurate information in order to address problems more effectively. The intuitionistic fuzzy theory’s most remarkable feature is that it has included the haziness and uncertainty of physical challenges and scientific problems better than the traditional fuzzy set accomplishes, for example in the areas of psychological analysis, decision-making, and strategies for a number of bio-informatics and computational biological-based problems. Decision-making involves studying and ranking a certain number of possibilities to determine how effective decision-makers are when all needs are continuously considered [7,8]. The notion of intuitionistic fuzzy subgroups was first suggested by Biswas [9]. In order to examine non-associative rings and other mathematical properties, numerous mathematicians have developed intuitionistic fuzzy sets and hybrid power frameworks of fuzzy sets [10,11]. Malik and Mordeson [12] introduced some fundamental characteristics of fuzzy subfield and provided an example of how to described a field expansions in terms of fuzzy subfield. Let

F

be a field; then, a fuzzy set

E = {j, ρ_{E} (j), {\bar{ρ}}_{E} (j)}

of

(F, +, .)

is a fuzzy subfield if

ρ_{E} (\hat{j_{1}} - \hat{j_{2}}) \geq {ρ_{E} (\hat{j_{1}}) \land ρ_{E} (\hat{j_{2}})}

and

ρ_{E} (\hat{j_{1}} {\hat{j_{2}}}^{- 1}) \geq {ρ_{E} (\hat{j_{1}}) \land ρ_{E} (\hat{j_{2}})}

{F - 0}

for all

j \in F

, where 0 is an additive identity for all

j, j_{1}, j_{2} \in F .

Mordeson [13] proposed the idea of fuzzy algebraic field extensions and established the circumstances under which a field extension has a singular maximum fuzzy field. All fuzzy intermediate fields with the sup property are used by Volf [14] to characterize extensions; chained intermediate fields are described and show that any fuzzy intermediate field of such an extension has the sup property. Tang et al. [15] introduced the idea of an intuitionistic fuzzy entropy derived symmetric implicational algorithm, and symmetric implicational principles and applications. Yang et al. [16] used the N-base encoding method for the representation of particles and designed a particle update mechanism based on the Hamming distance and a fuzzy learning strategy, which can be performed in the discrete space.

In 2013, Yager [17,18] created the notion of a Pythagorean fuzzy subset

(\ddot{P} \ddot{F} \ddot{S} \ddot{S})

, where the squares of belonging and not belonging degrees add up to a range [0,1]. Therefore,

ρ (w) : W \to [0, 1], \bar{ρ} (w) : W \to [0, 1], w \in W, {(ρ_{W} (w))}^{2} + {({\bar{ρ}}_{W} (w))}^{2} \leq 1

. Our understanding of problem solving in decision making has significantly benefited from

\ddot{P} \ddot{F} \ddot{S} \ddot{S}

. Peng and Yang [19] suggested the importance of two operations, division and subtraction, and discussed each of their features in order to clarify

\ddot{P} \ddot{F} \ddot{S} s

. After that, the boundness, idempotency, and homogeneity properties of

\ddot{P} \ddot{F}

analytic functions were examined. Li and Lu [20] defined the

\ddot{P} \ddot{F}

normalised Hamming distance, and

\ddot{P} \ddot{F}

normalised Hausdorff distance by extending the Hamming distance and the Hausdorff distance with

\ddot{P} \ddot{F} \ddot{S} s

. Ejegwa [21] adopted

\ddot{P} \ddot{F} \ddot{S} s

because they have many different applications and are extended intuitionistic fuzzy sets. It is crucial to consider how inventive such sets are in addressing the problem of career placements. He also talked about choosing a good profession based on academic ability and demonstrated how to do this using the suggested method. Ejegwa [22] developed the technique of the max–min–max composite relation for

\ddot{P} \ddot{F} \ddot{S} s

. The application of the enhanced composite relation for

\ddot{P} \ddot{F} \ddot{S} s

in medical diagnostics was examined using a hypothetical medical database. Yager [23] presented the novel notion of a q-rung orthopair fuzzy set (

q - \ddot{R} \ddot{O} \ddot{F} \ddot{F}

) in 2017. Both the intuitionistic fuzzy set and the

\ddot{P} \ddot{F} \ddot{S}

are generalized versions of these. The entire sum of the qth powers of supporting and non-supporting is to range [0,1] in the

q - \ddot{R} \ddot{O} \ddot{F} \ddot{S}

. As q increases, a wider variety of valid orthopairs become available, allowing for a conceptually much more expansive discussion of the membership score.

By utilising various significant tools, Ali [24] restructured the

q - \ddot{R} \ddot{O} \ddot{F} \ddot{F}

. He also described the fundamental algebraic operations under action of widely used in classification problems of

q - \ddot{R} \ddot{O} \ddot{F} \ddot{S} s

and presented the orbit-based

q - \ddot{R} \ddot{O} \ddot{F} \ddot{S}

with the aid of illustrations and examples. If supporting score

ρ (w)

and non-supporting score

\bar{ρ} (w)

is to bounded by 1,

ρ (u)

:

W \to [0, 1], \bar{ρ} (w) : T \to [0, 1], w \in W {(ρ_{W} (w))}^{q} + {({\bar{ρ}}_{W} (w))}^{q} \leq 1

. For

q - \ddot{R} \ddot{O} \ddot{F} \ddot{S} s

, Peng [25] investigated the connection between the measurements of inclusion, likeness, distance, and entropy. He also demonstrated the validity of the similarity measure, which was then used for pattern recognition, density estimation, and clinical issues. Wang et al. [26] developed the ten similarity measures by examining at the roles of belonging degree, not belonging degree, and indeterminacy belonging degree among the

q - \ddot{R} \ddot{O} \ddot{F} \ddot{S} s

based on cotangent and the traditional cosine similarity measurements. Additionally,

q - \ddot{R} \ddot{O} \ddot{F} \ddot{S} s

were employed to handle multi-objective decision. The

q - \ddot{R} \ddot{O} \ddot{F}

subgroup was a novel idea introduced by Asima and Razaq [27], who also developed several significant findings. We expand on our examination of

q - \ddot{R} \ddot{O} \ddot{F} \ddot{S} s

by creating a new notion for

q - \ddot{R} \ddot{O} \ddot{F}

subfield and by establishing some fresh findings under its influence. The

q - \ddot{R} \ddot{O} \ddot{F} \ddot{S}

is capable of solving a wide range of field theory issues. For their next research projects, mathematicians will find this theory helpful.

In this article, we present the

q - \ddot{R} \ddot{O} \ddot{F}

subfield. In Section 2, we illustrate some fundamental mathematical properties of the

q - \ddot{R} \ddot{O} \ddot{F}

subfield. In Section 3, we initiate the novel concepts of the

q - \ddot{R} \ddot{O} \ddot{F}

subfield and discuss its criteria and basics properties. Also, we show that every Pythagorean fuzzy subfield is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of certain field. Moreover, we establish some important basic theorems of

q - \ddot{R} \ddot{O} \ddot{F}

subfield and an example is provided to demonstrate the suitability and effectiveness of the initiated model. In Section 4, we establish the images and pre-images of

q - \ddot{R} \ddot{O} \ddot{F}

subfield under field homomorphism. In Section 5, we bring our proposed ideolody to a strong conclusion.

2. Preliminaries

In this section, the

q - \ddot{R} \ddot{O} \ddot{F}

field is defined and some of its basic algebraic features are discussed.

Definition 1

([3]).Suppose that

T

is a classical set; therefore,

δ (u) : T \to [0, 1]

is known as fuzzy subset of

T

and δ represents a supporting degree of

u \in T

such that

0 \leq δ (u) \leq 1 .

Definition 2

([12]).Assume that

(F, +, .)

is a field; then, fuzzy set

E = {(d, t, Φ_{E} (d), {\bar{Φ}}_{E} (d)); d \in F}

of

(F, +, .)

is known as a fuzzy subfield of

F

if the given axioms hold:

1.: $Φ_{E} (d - t) \geq {Φ_{E} (d) \land Φ_{E} (t)}$ ;
2.: $Φ_{E} (d t) \geq {Φ_{E} (d) \land Φ_{E} (t)}$ ; therefore, 0 is an additive identity;
3.: $Φ_{E} (d^{- 1}) \geq Φ_{E} (d), for all d \in F / {0}$ .

Definition 3

([6]).Let

V

be an intuitionistic fuzzy set on a crisp set

T

defined as

V = {(i, Φ_{V} (i), {\bar{Φ}}_{V} (i)); i \in T},

where

Φ (i)

and

\bar{Φ} (i)

represent membership and non-membership values, respectively, for all

i \in T

and satisfy the following condition:

0 \leq Φ (i) + \bar{Φ} (i) \leq 1

.

Definition 4

([13]).Assume that

(F, +, .)

is a field; then, an intuitionistic fuzzy set

E = {(d, t, Φ_{E} (d), {\bar{Φ}}_{E} (d)); d \in F}

of

(F, +, .)

is known as an intuitionistic fuzzy subfield of

F

if the given axioms hold:

1.: $Φ_{E} (d - t) \geq {Φ_{E} (d) \land Φ_{E} (t)}$ ;
2.: ${\bar{Φ}}_{E} (d t) \leq {{\bar{Φ}}_{E} (d) \lor {\bar{Φ}}_{E} (t)}$ , for all $d \in F$ , where 0 is an additive identity;
3.: $Φ_{E} (d t) \geq {Φ_{E} (d) \land Φ_{E} (t)}$ ;
4.: ${\bar{Φ}}_{E} (d t) \leq {{\bar{Φ}}_{E} (d) \lor {\bar{Φ}}_{E} (t)}$ ;
5.: $Φ_{E} (d^{- 1}) \geq Φ_{E} (d)$ ;
6.: ${\bar{Φ}}_{E} (d^{- 1}) \leq {\bar{Φ}}_{E} (d),$ $for all d \in F / {0}$ .

Definition 5

([17]).A

\ddot{P} \ddot{F} \ddot{S}

on crisp set

T

is define as

E = {(i, Φ_{E} (i), {\bar{Φ}}_{E} (i)); i \in T}

of

(F, +, .)

, where

Φ_{E} (i) ⟶ [0, 1]

and

{\bar{Φ}}_{E} (i) ⟶ [0, 1]

, represent membership and non-membership values, respectively, for all

i \in T

and satisfy the following condition:

0 \leq {(Φ (i))}^{2} + {(\bar{Φ} (i))}^{2} \leq 1 \forall i \in T

.

Example 1.

Let K be a q-Rung Orthopair fuzzy set. Assume that

ϕ_{T} (y) = 0.75

,

{\bar{ϕ}}_{T} (y) = 0.8

for

Y = {y}

. Clearly,

0.8 + 0.75 ≰ 1

, but

{(0.8)}^{3} + {(0.4)}^{3} \leq 1

. Hence, A is not an intuitionistic fuzzy set, but it is 3-rung Orthopair fuzzy subset.

Definition 6

([27]).Assume that

(F, +, .)

is a field; then, a

\ddot{P} \ddot{F} \ddot{S}

E = {(i, Φ_{E} (i), {\bar{Φ}}_{E} (i)); i \in F}

of

(F, +, .)

is known as a

\ddot{P} \ddot{F}

subfield of

F

if the given axioms hold:

1.: ${(Φ_{E} (i_{1} - i_{2}))}^{2} \geq {{(Φ_{E} (i_{1}))}^{2} \land {(Φ_{E} (i_{2}))}^{2}}$ ;
2.: ${({\bar{Φ}}_{E} (i_{1} - i_{2}))}^{2} \leq {{({\bar{Φ}}_{E} (i_{1}))}^{2} \lor {({\bar{Φ}}_{E} (i_{2}))}^{2}}$ , for all $i \in F$ , where 0 is an additive identity;
3.: ${(Φ_{E} (i_{1} i_{2}))}^{2} \geq {{(Φ_{E} (i_{1}))}^{2} \land {(Φ_{E} (i_{2}))}^{2}}$ ;
4.: ${({\bar{Φ}}_{E} (i_{1} i_{2}))}^{2} \leq {{({\bar{Φ}}_{E} (i_{1}))}^{2} \lor {({\bar{Φ}}_{E} (i_{2}))}^{2}}$ ;
5.: ${(Φ_{E} (i^{- 1}))}^{2} \geq {(Φ_{E} (i))}^{2}$ ;
6.: ${({\bar{Φ}}_{E} (i^{- 1}))}^{2} \leq {({\bar{Φ}}_{E} (i))}^{2}$ , $for all i \in F / {0}$ .

3. The q-Rung Orthopair Fuzzy Subfield

In this section, we define the

q - \ddot{R} \ddot{O} \ddot{F}

subfield, and some fundamental algebraic attributes of the

q - \ddot{R} \ddot{O} \ddot{F}

subfield are examined.

Definition 7.

Assume that

(F, +, .)

is a field; then, a

q - \ddot{R} \ddot{O} \ddot{F} \ddot{S}

E = {(t, Φ_{E} (t), {\bar{Φ}}_{E} (t)); t \in F}

of

(F, +, .)

is known as a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

if the given axioms hold:

1.: ${(Φ_{E} (t_{1} - t_{2}))}^{q} \geq {{(Φ_{E} (t_{1}))}^{q} \land {(Φ_{E} (t_{2}))}^{q}}$ ;
2.: ${({\bar{Φ}}_{E} (t_{1} - t_{2}))}^{q} \leq {{({\bar{Φ}}_{E} (t_{1}))}^{q} \lor {({\bar{Φ}}_{E} (t_{2}))}^{q}}$ , for all $t \in F$ , where 0 is an additive identity;
3.: ${(Φ_{E} (t_{1} t_{2}))}^{q} \geq {{(Φ_{E} (t_{1}))}^{q} \land {(Φ_{E} (t_{2}))}^{q}}$ ;
4.: ${({\bar{Φ}}_{E} (t_{1} t_{2}))}^{q} \leq {{({\bar{Φ}}_{E} (t_{1}))}^{q} \lor {({\bar{Φ}}_{E} (t_{2}))}^{q}}$ ;
5.: ${(Φ_{E} (t^{- 1}))}^{q} \geq {(Φ_{E} (t))}^{q}$ ;
6.: ${({\bar{Φ}}_{E} (t^{- 1}))}^{q} \leq {({\bar{Φ}}_{E} (t))}^{q},$ $for all t \in F / {0}$ .

Definition 8.

Suppose that

V

is a fuzzy subfield of field

(F, +, .)

for any i and

c \neq 0

in

F

,

_{i} V_{c}

is defined by

(i + V) (c) = V (- i + c)

for all u in F, and

(i V) (c) = (V) (i^{- 1} c)

\forall c

in F is called a fuzzy (i, c) co-set of

F

.

Definition 9.

Let

V

be a fuzzy subfield of field

(F, +, .)

and

H = {V (i) = V (0) = V (1); i \in F}

; then,

O (V)

, order of V, is defined as

O (V) = O (H)

, where 0 is an additive and 1 is a multiplicative identity element of

F

.

Theorem 1.

Let

E = {(ℏ, Φ_{E} (ϑ), {\bar{Φ}}_{E} (ϑ)), {(Φ_{E} (ϑ))}^{q} + {({\bar{Φ}}_{E} (ϑ))}^{q} \leq 1 : ϑ \in F}

be a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

; then, the following axioms hold:

1.: ${(Φ_{E} (0))}^{q} \geq {(Φ_{E} (ϑ))}^{q}$ and ${({\bar{Φ}}_{E} (0))}^{q} \leq {({\bar{Φ}}_{E} (ϑ))}^{q}$ for all $ϑ \in F$ ;
2.: ${(Φ_{E} (ϑ^{- 1}))}^{q} \geq {(Φ_{E} (ϑ))}^{q}$ and ${({\bar{Φ}}_{E} (ϑ^{- 1}))}^{q} \leq {({\bar{Φ}}_{E} (ϑ))}^{q}$ , $for all ϑ \in F / {0}$ ;
3.: ${(Φ_{E} (1))}^{q} \geq {(Φ_{E} (ϑ))}^{q}$ and ${({\bar{Φ}}_{E} (1))}^{q} \leq {({\bar{Φ}}_{E} (ϑ))}^{q}$ for all $ϑ \in F$ ;
4.: ${(Φ_{E} (- ϑ))}^{q} = {(Φ_{E} (ϑ))}^{q}$ and ${({\bar{Φ}}_{E} (ϑ))}^{q} = {({\bar{Φ}}_{E} (ϑ))}^{q}$ for all $ϑ \in F$ .

Proof.

Suppose that $ϑ \in F$ , then

$\begin{matrix} {(Φ_{E} (0))}^{q} & = & {(Φ_{E} (ϑ - ϑ))}^{q} \\ \geq & {{(Φ_{E} (ϑ))}^{q} \land {(Φ_{E} (- ϑ))}^{q}} \\ = & {(Φ_{E} (ϑ))}^{q} \\ {(Φ_{E} (0))}^{q} & \geq & {(Φ_{E} (ϑ))}^{q} for all ϑ \in F . \\ By Definition (7), & \Rightarrow & {(Φ_{E} (ϑ^{- 1}))}^{q} \geq {(Φ_{E} (ϑ))}^{q}, \\ \Rightarrow & {(Φ_{E} (1))}^{q} \geq {(Φ_{E} (ϑ))}^{q} for all ϑ \in F / {0}, \\ In similar fashion, {({\bar{Φ}}_{E} (0))}^{q} & = & {({\bar{Φ}}_{E} (ϑ - ϑ))}^{q} \\ \leq & {{({\bar{Φ}}_{E} (ϑ))}^{q} \lor {({\bar{Φ}}_{E} (- ϑ))}^{q}} \\ = & {({\bar{Φ}}_{E} (ϑ))}^{q} \end{matrix}$

$\begin{matrix} {({\bar{Φ}}_{E} (0))}^{q} & \leq & {({\bar{Φ}}_{E} (ϑ))}^{q} for all ϑ \in F . \\ By Definition (7) & \Rightarrow & {({\bar{Φ}}_{E} (ϑ^{- 1}))}^{q} \leq {({\bar{Φ}}_{E} (ϑ))}^{q}, \\ \Rightarrow & {({\bar{Φ}}_{E} (1))}^{q} \leq {({\bar{Φ}}_{E} (ϑ))}^{q} . \end{matrix}$

${(Φ_{E} (- ϑ))}^{q} \geq ({(Φ_{E} (ϑ))}^{q}$ and ${({\bar{Φ}}_{E} (- ϑ))}^{q} \leq {({\bar{Φ}}_{E} (ϑ))}^{q}$ for all $ϑ \in F$ . Therefore, ${(Φ_{E} (- (- ϑ)))}^{q} \geq ({(Φ_{E} (- ϑ))}^{q}$ and ${({\bar{Φ}}_{E} (- (- ϑ)))}^{q} \leq {({\bar{Φ}}_{E} (- ϑ))}^{q}$ , which implies that ${(Φ_{E} (ϑ))}^{q} \geq ({(Φ_{E} (- \tilde{ϑ}))}^{q}$ and ${({\bar{Φ}}_{E} (ϑ))}^{q} \leq ({({\bar{Φ}}_{E} (- ϑ))}^{q}$ . Thus, ${(Φ_{E} (- ϑ))}^{q} = ({(Φ_{E} (ϑ))}^{q}$ and ${({\bar{Φ}}_{E} (- ϑ))}^{q} = ({({\bar{Φ}}_{E} (ϑ))}^{q}$ for all $ϑ \in F .$

□

Theorem 2.

Let

E = {(ϑ, Φ_{E} (ϑ), {\bar{Φ}}_{K} (ϑ)), {(Φ_{E} (ϑ))}^{q} + {({\bar{Φ}}_{E} (ϑ))}^{q} \leq 1 : ϑ \in F}

be a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

; then, the following axioms hold:

1.: ${(Φ_{E} (ϑ - \tilde{c}))}^{q} = {(Φ_{E} (0))}^{q}$ gives ${(Φ_{E} (ϑ))}^{q} = {(Φ_{E} (\tilde{c}))}^{q}$ and ${({\bar{Φ}}_{E} (ϑ - \tilde{c}))}^{q} = {({\bar{Φ}}_{E} (0))}^{q}$ gives ${({\bar{Φ}}_{E} (ϑ))}^{q} = {({\bar{Φ}}_{E} (\tilde{c}))}^{q}$ for all ϑ and $c \in F,$
2.: ${(Φ_{E} (ϑ {\tilde{c}}^{- 1}))}^{q} = {(Φ_{E} (1))}^{q}$ gives ${(Φ_{E} (ϑ))}^{q} = {(Φ_{E} (\tilde{c}))}^{q}$ and ${({\bar{Φ}}_{E} (ϑ {\tilde{c}}^{- 1}))}^{q} = {({\bar{Φ}}_{E} (1))}^{q}$ gives ${({\bar{Φ}}_{E} (ϑ))}^{q} = {({\bar{Φ}}_{E} (\tilde{c}))}^{q}$ for all ϑ and $c \neq 0 i n F$ , where 0 and 1 are additive and multiplicative identity elements, respectively, in $F$ .

Proof.

Suppose that

ϑ, \tilde{c} \in F

, and

0, 1

are the additive and multiplicative identity elements, respectively, in

F .

Suppose that $ϑ, \tilde{c} \in F$ ; then,

$\begin{matrix} {(Φ_{E} (ϑ))}^{q} = {(Φ_{E} (ϑ - \tilde{c} + \tilde{c}))}^{q} & \geq & {{(Φ_{E} (ϑ - \tilde{c}))}^{q} \land {(Φ_{E} (\tilde{c}))}^{q}} \\ = & {{(Φ_{E} (0))}^{q} \land {(Φ_{E} (\tilde{c}))}^{q}} \\ = & {(Φ_{E} (\tilde{c}))}^{q} \\ = & {(Φ_{E} (ϑ - (ϑ - \tilde{c})))}^{q} \\ \geq & {{(Φ_{E} (ϑ - \tilde{c}))}^{q} \land {(Φ_{E} (ϑ))}^{q}} \\ = & {{(Φ_{E} (0))}^{q} \land {(Φ_{E} (ϑ))}^{q}} \\ = & {(Φ_{E} (ϑ))}^{q} . \end{matrix}$

Therefore, ${(Φ_{E} (ϑ))}^{q} = {(Φ_{E} (\tilde{c}))}^{q}$ for all $\tilde{c} \in F .$ In the same fashion,

$\begin{matrix} {({\bar{Φ}}_{E} (ϑ))}^{q} = {({\bar{Φ}}_{E} (ϑ - \tilde{c} + \tilde{c}))}^{q} & \leq & {{({\bar{Φ}}_{E} (ϑ - \tilde{c}))}^{q} \lor {({\bar{Φ}}_{E} (\tilde{c}))}^{q}} \\ = & {{({\bar{Φ}}_{E} (0))}^{q} \lor {({\bar{Φ}}_{E} (\tilde{c}))}^{q}} \\ = & {({\bar{Φ}}_{E} (\tilde{c}))}^{q} \\ = & {({\bar{Φ}}_{E} (ϑ - (ϑ - \tilde{c})))}^{q} \\ \leq & {{({\bar{Φ}}_{E} (ϑ - \tilde{c}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ))}^{q}} \\ = & {{({\bar{Φ}}_{E} (0))}^{q} \lor {({\bar{Φ}}_{E} (ϑ))}^{q}} \\ = & {({\bar{Φ}}_{E} (ϑ))}^{q} \end{matrix}$

Therefore, ${({\bar{Φ}}_{E} (ϑ))}^{q} = {({\bar{Φ}}_{E} (\tilde{c}))}^{q}$ for all $ϑ, \tilde{c} \in F$ .
Moreover,

$\begin{matrix} {(Φ_{E} (ϑ))}^{q} & = & {(Φ_{E} (ϑ {\tilde{c}}^{- 1} \tilde{c}))}^{q} \\ \geq & {{(Φ_{E} (ϑ {\tilde{c}}^{- 1}))}^{q} \land {(Φ_{E} (\tilde{c}))}^{q}} \\ \geq & {{(Φ_{E} (1))}^{q} \land {(Φ_{E} (\tilde{c}))}^{q}} \\ = & {(Φ_{E} (\tilde{c}))}^{q} \\ = & {(Φ_{E} ({(ϑ {\tilde{c}}^{- 1})}^{- 1} ϑ))}^{q} \\ \geq & {{(Φ_{E} (ϑ {\tilde{c}}^{- 1}))}^{q} \land {(Φ_{E} (ϑ))}^{q}} \end{matrix}$

$\begin{matrix} \geq & {{(Φ_{E} (1))}^{q} \land {(Φ_{E} (ϑ))}^{q}} \\ = & {(Φ_{E} (ϑ))}^{q} \end{matrix}$

Therefore, ${(Φ_{E} (ϑ))}^{q} = {(Φ_{E} (\tilde{c}))}^{q} for all ϑ, \tilde{c} \neq 0 \in F .$ Furthermore,

$\begin{matrix} {({\bar{Φ}}_{E} (ϑ))}^{q} & = & {({\bar{Φ}}_{E} (ϑ {\tilde{c}}^{- 1} \tilde{c}))}^{q} \\ \leq & {{({\bar{Φ}}_{E} (ϑ {\tilde{c}}^{- 1}))}^{q} \lor {({\bar{Φ}}_{E} (\tilde{c}))}^{q}} \\ \leq & {{({\bar{Φ}}_{E} (1))}^{q} \lor {({\bar{Φ}}_{E} (\tilde{c}))}^{q}} \\ = & {({\bar{Φ}}_{E} (\tilde{c}))}^{q} \\ {({\bar{Φ}}_{E} (\tilde{c}))}^{q} & = & {({\bar{Φ}}_{E} ({(ϑ {\tilde{c}}^{- 1})}^{- 1} ϑ))}^{q} \\ \leq & {{({\bar{Φ}}_{E} (ϑ {\tilde{c}}^{- 1}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ))}^{q}} \\ \leq & {{({\bar{Φ}}_{E} (1))}^{q} \lor {({\bar{Φ}}_{E} (ϑ))}^{q}} \\ = & {({\bar{Φ}}_{E} (ϑ))}^{q} . \end{matrix}$

Therefore, ${({\bar{Φ}}_{E} (ϑ))}^{q} = {({\bar{Φ}}_{E} (\tilde{c}))}^{q}$ for all $ϑ, \tilde{c} \neq 0 \in F$ . Hence, this illustrates the proof.

□

Example 2.

Let

F = Z

be a field, where

Z_{3} = {\bar{0}, \bar{1}, \bar{2},}

and

L = {< u, Φ (i), \bar{Φ} (i) > u \in Z_{3}}

is not a Pythagoran fuzzy subfield over

Z_{3}

, defined as

Φ_{L} (b) = \{\begin{matrix} 0.75 & if u \in {\bar{1}, \bar{2}} \\ 0.8 & if u \in {0} \end{matrix}

and

{\bar{Φ}}_{L} (b) = \{\begin{matrix} 0.8 & if u \in {\bar{1}, \bar{2}} \\ 0.75 & if u \in {0} \end{matrix}

Clearly, L is a q-rung orthopair fuzzy subfield of

Z_{3}

for

q \geq 3

but it is not a pythagorean fuzzy subfield of

Z_{3}

as

{(0.75)}^{2} + {(0.8)}^{2} > 1 .

Theorem 3.

If

E = {(ϑ, Φ_{E} (ϑ), {\bar{Φ}}_{E} (ϑ)) : ϑ \in F}

is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of field

(F, +, .)

if and only if

1.: ${(Φ_{E} (ϑ_{1} - ϑ_{2}))}^{q} \geq {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (ϑ_{2}))}^{q}}$ and ${({\bar{Φ}}_{E} (ϑ_{1} - ϑ_{2}))}^{q} \leq {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ_{2}))}^{q}}$ for all $i \in F$ ,
2.: ${(Φ_{E} (ϑ_{1} ϑ_{2}^{- 1}))}^{q} \geq {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (ϑ_{2}))}^{q}}$ and ${({\bar{Φ}}_{E} (ϑ_{1} ϑ_{2}^{- 1}))}^{q} \leq {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor$ ${({\bar{Φ}}_{E} (ϑ_{2}))}^{q}}$ for all $ϑ \in F / {0}$ .

Proof.

Let E be a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of field

(F, +, .)

and all

ϑ \in F

.

\begin{matrix} Then, {(Φ_{E} (ϑ_{1} - ϑ_{2}))}^{q} & \geq & {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (- ϑ_{2}))}^{q}} \\ = & {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (ϑ_{2}))}^{q}} \\ Therefore, {(Φ_{E} (ϑ_{1} - ϑ_{2}))}^{q} & \geq & {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (ϑ_{2}))}^{q}} \forall ϑ \in F . \\ Similarly, {({\bar{Φ}}_{E} (ϑ_{1} - ϑ_{2}))}^{q} & \leq & {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (- ϑ_{2}))}^{q}} \\ = & {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ_{2}))}^{q}} \\ So, {({\bar{Φ}}_{E} (ϑ_{1} - ϑ_{2}))}^{q} & \leq & {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ_{2}))}^{q}} \forall ϑ \in F . \end{matrix}

\begin{matrix} And, {(Φ_{E} (ϑ_{1} ϑ_{2}^{- 1}))}^{q} & \geq & {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (ϑ_{2}^{- 1}))}^{q}} \\ = & {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (ϑ_{2}))}^{q}} \\ Thus, {(Φ_{E} (ϑ_{1} ϑ_{2}^{- 1}))}^{q} & \geq & {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (ϑ_{2}))}^{q}} \forall ϑ \in F / {0} . \\ In the same way, {({\bar{Φ}}_{E} (ϑ_{1} ϑ_{2}^{- 1}))}^{q} & \leq & {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ_{2}^{- 1}))}^{q}} \\ = & {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ_{2}))}^{q}} \\ We obtain, {({\bar{Φ}}_{E} (ϑ_{1} ϑ_{2}^{- 1}))}^{q} & \leq & {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ_{2}))}^{q}} \forall ϑ \in F / {0} . \end{matrix}

Conversely, if

{(Φ_{E} (ϑ_{1} - ϑ_{2}))}^{q} \geq {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (ϑ_{2}))}^{q}}

,

{({\bar{Φ}}_{E} (ϑ_{1} - ϑ_{2}))}^{q} \leq {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ_{2}))}^{q}} \forall ϑ \in F

,

{(Φ_{E} (ϑ_{1} ϑ_{2}^{- 1}))}^{q} \geq {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (ϑ_{2}))}^{q}}

and

{({\bar{Φ}}_{E} (ϑ_{1} ϑ_{2}^{- 1}))}^{q} \leq {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ_{2}))}^{q}} \forall ϑ \in F / {0} .

Replace

ϑ_{1}

by

ϑ_{2}

; then, we obtain

{(Φ_{E} (ϑ_{1}))}^{q} \leq {(Φ_{E} (0))}^{q}

and

{(Φ_{E} (ϑ_{1}))}^{q} \leq {(Φ_{E} (1))}^{q}

for all

ϑ \in F .

Then,

\begin{matrix} {(Φ_{E} (- ϑ_{1}))}^{q} & = & {(Φ_{E} (0 - ϑ_{1}))}^{q} \\ {(Φ_{E} (- ϑ_{1}))}^{q} & \geq & {{(Φ_{E} (0))}^{q} \land {(Φ_{E} (ϑ_{1}))}^{q}} \\ = & {(Φ_{E} (ϑ_{1}))}^{q} \\ Therefore, {(Φ_{E} (- ϑ_{1}))}^{q} & \geq & {(Φ_{E} (ϑ_{1}))}^{q} for all ϑ \in F . \\ Also, {({\bar{Φ}}_{E} (- ϑ_{1}))}^{q} & = & {({\bar{Φ}}_{E} (0 - ϑ_{1}))}^{q} \\ {({\bar{Φ}}_{E} (ϑ_{1}))}^{q} & \leq & {{({\bar{Φ}}_{E} (0))}^{q} \lor {({\bar{Φ}}_{E} (ϑ_{1}))}^{q}} \\ = & {({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \\ Therefore, {({\bar{Φ}}_{E} (ϑ_{1}))}^{q} & \leq & {({\bar{Φ}}_{E} (ϑ_{1}))}^{q} for all ϑ \in F . \\ Furthermore, {(Φ_{E} (ϑ_{1}^{- 1}))}^{q} & = & {(Φ_{E} (ϑ_{1}^{- 1} 1))}^{q} \\ {(Φ_{E} (ϑ_{1}^{- 1}))}^{q} & \geq & {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (1))}^{q}} \\ = & {(Φ_{E} (ϑ_{1}))}^{q} . \\ Consequently, {(Φ_{E} (ϑ_{1}^{- 1}))}^{q} & \geq & {(Φ_{E} (ϑ_{1}))}^{q} for all for all ϑ \in F / {0} . \\ Also, {({\bar{Φ}}_{E} (ϑ_{1}^{- 1}))}^{q} & = & {({\bar{Φ}}_{E} (ϑ_{1}^{- 1} 1))}^{q} \\ {({\bar{Φ}}_{E} i_{1}^{- 1}))}^{q} & \leq & {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (1))}^{q}} \\ = & {({\bar{Φ}}_{E} (ϑ_{1}))}^{q} . \\ So, {({\bar{Φ}}_{E} (ϑ_{1}^{- 1}))}^{q} & \leq & {({\bar{Φ}}_{E} (ϑ_{1}))}^{q} ϑ \in F / {0} . \\ Now, {(Φ_{E} (ϑ_{1} + ϑ_{2}))}^{q} & = & {(Φ_{E} {(ϑ_{1} - (- ϑ_{2}))}^{q} \\ \geq & {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (- ϑ_{2}))}^{q}} \\ = & {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (ϑ_{2}))}^{q}} . \end{matrix}

\begin{matrix} Therefore, {(Φ_{E} (ϑ_{1} + ϑ_{2}))}^{q} & \leq & {{(Φ_{E} (ϑ_{1}))}^{q} \lor {(Φ_{E} (ϑ_{2}))}^{q}} for all ϑ \in F . \\ And, {({\bar{Φ}}_{E} (ϑ_{1} + ϑ_{2}))}^{q} & = & {({\bar{Φ}}_{E} {(ϑ_{1} - (- ϑ_{2}))}^{q} \\ \leq & {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (- ϑ_{2}))}^{q}} \\ = & {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ_{2}))}^{q}} \\ Then, consequently, {({\bar{Φ}}_{E} (ϑ_{1} + ϑ_{2}))}^{q} & \leq & {{(v Φ_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ_{2}))}^{q}} for all ϑ \in F . \end{matrix}

\begin{matrix} Additionally, {(Φ_{E} (ϑ_{1} ϑ_{2}))}^{q} & = & {(Φ_{E} {(ϑ_{1} (ϑ_{2}^{- 1}))}^{- 1})}^{q} \\ \geq & {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (ϑ_{2}^{- 1}))}^{q}} \\ = & {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (ϑ_{2}))}^{q}} . \\ Thus, {(Φ_{E} (ϑ_{1} ϑ_{2}))}^{q} & \geq & {{(Φ_{E} (ϑ_{1}))}^{q} \land {(Φ_{E} (ϑ_{2}))}^{q}} for all ϑ \in F / {0} . \\ In the same way, {({\bar{Φ}}_{E} (ϑ_{1} ϑ_{2}))}^{q} & = & {({\bar{Φ}}_{E} {(ϑ_{1} (ϑ_{2}^{- 1}))}^{- 1})}^{q} \\ {({\bar{Φ}}_{E} (ϑ_{1} ϑ_{2}))}^{q} & \leq & {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ_{2}^{- 1}))}^{q}} \\ = & {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ_{2}))}^{q}} . \\ We obtain {({\bar{Φ}}_{E} (ϑ_{1} ϑ_{2}^{- 1}))}^{q} & \leq & {{({\bar{Φ}}_{E} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{E} (ϑ_{2}))}^{q}} for all ϑ \in F / {0} . \end{matrix}

Hence, E is a fuzzy subfield of field

F .

□

Theorem 4.

Suppose that

F

is a field and

M = {(ϑ, Φ_{M} (ϑ), {\bar{Φ}}_{M} (ϑ)), {(Φ_{M} (ϑ))}^{2} + {({\bar{Φ}}_{M} (ϑ))}^{2} \leq 1 : ϑ \in F}

is a

\ddot{P} \ddot{F}

subfield of

F

; then,

M

is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

.

Proof.

Assume that

ϑ_{1}, ϑ_{2} \in F

; then,

\begin{matrix} {(Φ_{M} (ϑ_{1} - ϑ_{2}))}^{2} & \geq & {{(Φ_{M} (ϑ_{1}))}^{2} \land {(Φ_{M} (ϑ_{2}))}^{2}} \\ {({\bar{Φ}}_{M} (ϑ_{1} - ϑ_{2}))}^{2} & \leq & {{({\bar{Φ}}_{M} (ϑ_{1}))}^{2} \lor {({\bar{Φ}}_{M} (ϑ_{2}))}^{2}} \\ {(Φ_{M} (ϑ_{1} ϑ_{2}))}^{2} & \geq & {{(Φ_{M} (ϑ_{1}))}^{2} \land {(Φ_{M} (ϑ_{2}))}^{2}} \\ {({\bar{Φ}}_{M} (ϑ_{1} ϑ_{2}))}^{2} & \leq & {{({\bar{Φ}}_{M} (ϑ_{1}))}^{2} \lor {({\bar{Φ}}_{M} (ϑ_{2}))}^{2}} \\ {(Φ_{M} (ϑ^{- 1}))}^{2} & \geq & {(Φ_{M} (ϑ))}^{2} \\ and {({\bar{Φ}}_{M} (ϑ^{- 1}))}^{2} & \leq & {({\bar{Φ}}_{M} (ϑ))}^{2} f o r a l l ϑ \in F . \end{matrix}

Furthermore,

\begin{matrix} {(Φ_{M} (ϑ_{1} - ϑ_{2}))}^{q} & \geq & {{(Φ_{M} (ϑ_{1}))}^{q} \land {(Φ_{M} (ϑ_{2}))}^{q}} \\ {({\bar{Φ}}_{M} (ϑ_{1} - ϑ_{2}))}^{q} & \leq & {{({\bar{Φ}}_{M} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{M} (ϑ_{2}))}^{q}} \forall ϑ \in F \\ {(Φ_{M} (ϑ_{1} ϑ_{2}))}^{q} & \geq & {{(Φ_{M} (ϑ_{1}))}^{q} \land {(Φ_{M} (ϑ_{2}))}^{q}} \\ {({\bar{Φ}}_{M} (ϑ_{1} ϑ_{2}))}^{q} & \leq & {{({\bar{Φ}}_{M} (ϑ_{1}))}^{q} \lor {({\bar{Φ}}_{M} (ϑ_{2}))}^{q}} \\ {(Φ_{M} (ϑ^{- 1}))}^{q} & \geq & {(Φ_{M} (ϑ))}^{q} \\ and {({\bar{Φ}}_{M} (ϑ^{- 1}))}^{q} & \leq & {({\bar{Φ}}_{M} (ϑ))}^{q} for all ϑ \in F / {0} . \end{matrix}

Thus,

{(Φ_{M} (ϑ_{1}))}^{2}, {(Φ_{M} (ϑ_{2}))}^{2}, {(Φ_{M} (ϑ))}^{2}, {(Φ_{M} (ϑ^{- 1}))}^{2}, {({\bar{Φ}}_{M} (ϑ_{1}))}^{2}, {({\bar{Φ}}_{M} (ϑ_{2}))}^{2}, {({\bar{Φ}}_{M} (ϑ))}^{2}

and

{({\bar{Φ}}_{M} (ϑ^{- 1}))}^{2} \in [0, 1] .

Therefore, for all

q > 1

, using

{(Φ_{M} (ϑ_{1}))}^{q} \leq {(Φ_{M} (ϑ_{1}))}^{2}

,

{(Φ_{M} (ϑ_{2}))}^{q} \leq {(Φ_{M} (ϑ_{2}))}^{2}, {(Φ_{M} (ϑ))}^{q} \leq {(Φ_{M} (ϑ))}^{2}, {({\bar{Φ}}_{M} (ϑ_{1}))}^{q} \geq {({\bar{Φ}}_{M} (ϑ_{1}))}^{2}, {({\bar{Φ}}_{M} (ϑ_{2}))}^{q} \geq {({\bar{Φ}}_{M} (ϑ_{2}))}^{2}, {(Φ_{M} (ϑ^{- 1}))}^{q} \leq {(Φ_{M} (ϑ))}^{q}, {({\bar{Φ}}_{E} (ϑ^{- 1}))}^{q} \leq {({\bar{Φ}}_{M} (ϑ))}^{q}

and

{({\bar{Φ}}_{M} (ϑ))}^{q} \geq {({\bar{Φ}}_{M} (ϑ))}^{2}

. So,

\begin{matrix} {{(Φ_{M} (ϑ_{1}))}^{q} + {({\bar{Φ}}_{M} (ϑ_{1}))}^{q} \leq 1} \end{matrix}

(1)

\begin{matrix} {{(Φ_{M} (ϑ_{2}))}^{q} + {({\bar{Φ}}_{M} (ϑ_{2}))}^{q} \leq 1} \end{matrix}

(2)

\begin{matrix} {{(Φ_{M} (ϑ))}^{q} + {({\bar{Φ}}_{M} (ϑ))}^{q} \leq 1} \end{matrix}

(3)

\begin{matrix} {{(Φ_{M} (ϑ^{- 1}))}^{q} + {({\bar{Φ}}_{M} (ϑ^{- 1}))}^{q} \leq 1} . \end{matrix}

(4)

These above expressions show that M is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

. □

Theorem 5.

q - \ddot{R} \ddot{O} \ddot{F} \ddot{S} \ddot{S}

T = {(ϱ, Φ_{T} (ϱ), {\bar{Φ}}_{T} (ϱ)) : c \in F}

of

F

is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

if and only if

{(Φ_{T} (c - ϱ))}^{q} \geq {{(Φ_{T} (c))}^{q} \land {(Φ_{T} (ϱ))}^{q}}

and

{({\bar{Φ}}_{T} (c - ϱ))}^{q} \leq {{({\bar{Φ}}_{T} (c))}^{q} \lor {({\bar{Φ}}_{T} (ϱ))}^{q}}

for all

c, ϱ \in F .

Proof.

Let

T = {(ϱ, Φ_{T} (ϱ), {\bar{Φ}}_{T} (ϱ)) : ϱ \in F, {(Φ_{T} (ϱ))}^{q} + {({\bar{Φ}}_{T} (ϱ))}^{q} \leq 1}

be a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

. Then for all

c, ϱ \in F

,

{(Φ_{T} (c - ϱ))}^{q} \geq {{(Φ_{T} (c))}^{q} \land {(Φ_{T} (- ϱ))}^{q}}

= {{(Φ_{T} (c))}^{q} \land {(Φ_{T} (ϱ))}^{q}}

and

{({\bar{Φ}}_{T} (c - ϱ))}^{q} \leq {{({\bar{Φ}}_{T} (c))}^{q} \lor {({\bar{Φ}}_{T} (- ϱ))}^{q}}

= {{({\bar{Φ}}_{T} (c))}^{q} \lor {({\bar{Φ}}_{T} (ϱ))}^{q}}

. Conversely, assume that

{(Φ_{T} (c - ϱ))}^{q} \geq {{(Φ_{T} (c))}^{q} \land {(Φ_{T} (ϱ))}^{q}}

and

{({\bar{Φ}}_{T} (c - ϱ))}^{q} \leq {{({\bar{Φ}}_{T} (c))}^{q} \lor {({\bar{Φ}}_{T} (ϱ))}^{q}}

for all

c, ϱ \in F .

Then,

{(Φ_{T} (c - ϱ))}^{q} = {(Φ_{T} (c - (- (- ϱ))))}^{q} \geq

{{(Φ_{T} (c))}^{q} \land {(Φ_{T} (- ϱ))}^{q}} = {{(Φ_{T} (c))}^{q} \land {(Φ_{T} (ϱ))}^{q}}

. Therefore,

{(Φ_{T} (c - ϱ))}^{q} \geq

{{(Φ_{T} (c))}^{q} \land {(Φ_{T} (ϱ))}^{q}}

. Similarly,

{({\bar{Φ}}_{T} (c - ϱ))}^{q} = {({\bar{Φ}}_{T} (c - (- (- ϱ))))}^{q} \leq {{({\bar{Φ}}_{T} (c))}^{q} \lor {({\bar{Φ}}_{T} (- ϱ))}^{q}} = {{({\bar{Φ}}_{T} (c))}^{q} \lor {({\bar{Φ}}_{T} (ϱ))}^{q}}

. Therefore,

{({\bar{Φ}}_{T} (c - ϱ))}^{q} \leq {{({\bar{Φ}}_{T} (c))}^{q} \lor {(Φ_{T} (ϱ))}^{q}}

. Next,

{(Φ_{T} (- ϱ))}^{q} = {(Φ_{T} (0 - ϱ))}^{q} \geq {{(Φ_{T} (0))}^{q} \land {(Φ_{T} (ϱ))}^{q}} = {(Φ_{T} (ϱ))}^{q}

, which means that

Φ_{T} {(- ϱ))}^{q} \geq {(Φ_{T} (ϱ))}^{q}

. In similar fashion, we have

{({\bar{Φ}}_{T} (- ϱ))}^{q} = {(Φ_{T} (0 - ϱ))}^{q} \leq {{({\bar{Φ}}_{T} (0))}^{q} \lor {({\bar{Φ}}_{T} (ϱ))}^{q}} = {({\bar{Φ}}_{T} (ϱ))}^{q}

. Then, obviously,

{(Φ_{T} (i^{- 1}))}^{q} \geq {(Φ_{T} (ϱ))}^{q}

and

{({\bar{Φ}}_{T} (i^{- 1}))}^{q} \leq {({\bar{Φ}}_{T} (ϱ))}^{q}

also hold. This implies that

{({\bar{Φ}}_{T} (- ϱ))}^{q} \leq {({\bar{Φ}}_{T} (ϱ))}^{q}

. Therefore, the expressions above demonstrate that

E

is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

. □

Theorem 6.

Let

{\dot{B}}_{1} = {(o, Φ_{\dot{B} 1} (o), {\bar{Φ}}_{\dot{B} 1} (o)) : o \in F}

and

{\dot{B}}_{2} = {(o, Φ_{\dot{B} 2} (o), {\bar{Φ}}_{\dot{B} 2} (o)) : o \in F}

be two

q - \ddot{R} \ddot{O} \ddot{F}

subfields of

F .

Then,

{\dot{B}}_{1} \cap {\dot{B}}_{2}

is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

.

Proof.

Let

{\dot{B}}_{1}

and

{\dot{B}}_{2}

be two

q - \ddot{R} \ddot{O} \ddot{F}

subfields of

F

. Then for all

o \in F

, we have

\begin{matrix} {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1} - o_{2}))}^{q} & = & {{(Φ_{\dot{B} 1} (o_{1} - o_{2}))}^{q} \land {(Φ_{\dot{B} 2} (o_{1} - o_{2}))}^{q}} \\ \geq & {{(Φ_{\dot{B} 1} (o_{1}))}^{q} \land {(Φ_{\dot{B} 1} (o_{2}))}^{q}} \land {{(Φ_{\dot{B} 2} (o_{1}))}^{q} \land {(Φ_{\dot{B} 2} (o_{2}))}^{q}} \\ = & ({(Φ_{\dot{B} 1} (o_{1}))}^{q} \land {(Φ_{\dot{B} 2} (o_{1}))}^{q}) \land ({(Φ_{\dot{B} 1} (o_{2}))}^{q} \land {(Φ_{\dot{B} 2} (o_{2}))}^{q}) \\ = & {{(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1}))}^{q} \land {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o_{2}))}^{q}} \\ {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1} - o_{2}))}^{q} & \geq & {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1}))}^{q} \land {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o_{2}))}^{q} . \end{matrix}

Moreover,

\begin{matrix} {({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1} - o_{2}))}^{q} & = & {{({\bar{Φ}}_{\dot{B} 1} (o_{1} - o_{2}))}^{q} \lor {({\bar{Φ}}_{\dot{B} 2} (o_{1} - o_{2}))}^{q}} \\ \leq & {{{({\bar{Φ}}_{\dot{B} 1} (o_{1}))}^{q} \lor {({\bar{Φ}}_{\dot{B} 1} (o_{2}))}^{q}} \lor {{({\bar{Φ}}_{\dot{B} 2} (o_{1}))}^{q} \lor {({\bar{Φ}}_{\dot{B} 2} (o_{2}))}^{q}}} \\ = & {({({\bar{Φ}}_{\dot{B} 1} (o_{1}))}^{q} \lor {({\bar{Φ}}_{\dot{B} 2} (o_{1}))}^{q}) \lor ({({\bar{Φ}}_{\dot{B} 1} (o_{2}))}^{q} \lor {({\bar{Φ}}_{\dot{B} 2} (o_{2}))}^{q})} \\ = & {{({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1}))}^{q} \lor {({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o_{2}))}^{q}} \\ {({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1} - o_{2}))}^{q} & \leq & {{({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1}))}^{q} \lor {({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o_{2}))}^{q}} f o r a l l o \in F . \end{matrix}

Then,

\begin{matrix} {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1} o_{2}))}^{q} & = & {{(Φ_{\dot{B} 1} (o_{1} o_{2}))}^{q} \land {(Φ_{\dot{B} 2} (o_{1} o_{2}))}^{q}} \\ \geq & {{(Φ_{\dot{B} 1} (o_{1}))}^{q} \land {(Φ_{\dot{B} 1} (o_{2}))}^{q}} \land {{(Φ_{\dot{B} 2} (o_{1}))}^{q} \land {(Φ_{\dot{B} 2} (o_{2}))}^{q}} \\ = & ({(Φ_{\dot{B} 1} (o_{1}))}^{q} \land {(Φ_{\dot{B} 2} (o_{1}))}^{q}) \land ({(Φ_{\dot{B} 1} (o_{2}))}^{q} \land {(Φ_{\dot{B} 2} (o_{2}))}^{q}) \\ = & {{(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1}))}^{q} \land {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o_{2}))}^{q}} \\ {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1} o_{2}))}^{q} & \geq & {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1}))}^{q} \land {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o_{2}))}^{q} f o r a l l o \in F / {0} . \end{matrix}

Similarly, we have

\begin{matrix} {({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1} o_{2}))}^{q} & = & {{({\bar{Φ}}_{\dot{B} 1} (o_{1} o_{2}))}^{q} \lor {({\bar{Φ}}_{\dot{B} 2} (o_{1} o_{2}))}^{q}} \\ \leq & {{{({\bar{Φ}}_{\dot{B} 1} (o_{1}))}^{q} \lor {({\bar{Φ}}_{\dot{B} 1} (o_{2}))}^{q}} \lor {{({\bar{Φ}}_{\dot{B} 2} (o_{1}))}^{q} \lor {({\bar{Φ}}_{\dot{B} 2} (o_{2}))}^{q}}} \\ = & {({({\bar{Φ}}_{\dot{B} 1} (o_{1}))}^{q} \lor {({\bar{Φ}}_{\dot{B} 2} (o_{1}))}^{q}) \lor ({({\bar{Φ}}_{\dot{B} 1} (o_{2}))}^{q} \lor {({\bar{Φ}}_{\dot{B} 2} (o_{2}))}^{q})} \\ = & {{({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1}))}^{q} \lor {({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o_{2}))}^{q}} \\ {({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1} - o_{2}))}^{q} & \leq & {{({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o_{1}))}^{q} \lor {({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o_{2}))}^{q}}, f o r a l l o \in F . \end{matrix}

Now, we conclude that

\begin{matrix} {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o^{- 1}))}^{q} & = & {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o^{- 1} 1))}^{q} = {{(Φ_{\dot{B} 1} (o^{- 1} 1))}^{q} \land {(Φ_{\dot{B} 2} (o^{- 1} 1))}^{q}} \\ \geq & {{(Φ_{\dot{B} 1} (o^{- 1}))}^{q} \land {(Φ_{\dot{B} 1} (1))}^{q}} \land {{(Φ_{\dot{B} 2} (o^{- 1}))}^{q} \land {(Φ_{\dot{B} 2} (1))}^{q}} \\ \geq & {{(Φ_{\dot{B} 1} (o))}^{q} \land {(Φ_{\dot{B} 1} (1))}^{q}} \land {{(Φ_{\dot{B} 2} (o))}^{q} \land {(Φ_{\dot{B} 2} (1))}^{q}} \\ = & {{(Φ_{\dot{B} 1} (o))}^{q} \land {(Φ_{\dot{B} 2} (o))}^{q}} \land {{(Φ_{\dot{B} 1} (1))}^{q} \land {(Φ_{\dot{B} 2} (1))}^{q}} \\ = & {{(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o^{- 1}))}^{q} \land {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (1))}^{q}}, f o r a l l o \in F / {0} . \end{matrix}

\begin{matrix} {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o^{- 1}))}^{q} & \geq & {{(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o))}^{q} \land {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (1))}^{q}} = {(Φ_{(\dot{B} 1 \cap \dot{B} 2)} (o))}^{q} . \\ and {({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o^{- 1}))}^{q} & = & {({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o^{- 1} 1))}^{q} = {{({\bar{Φ}}_{\dot{B} 1} (o^{- 1} 1))}^{q} \land {({\bar{Φ}}_{\dot{B} 2} (o^{- 1} 1))}^{q}} \\ \geq & {{({\bar{Φ}}_{\dot{B} 1} (o^{- 1}))}^{q} \land {({\bar{Φ}}_{\dot{B} 1} (1))}^{q}} \land {{({\bar{Φ}}_{\dot{B} 2} (o^{- 1}))}^{q} \land {({\bar{Φ}}_{\dot{B} 2} (1))}^{q}} \\ \geq & {{({\bar{Φ}}_{\dot{B} 1} (o))}^{q} \land {({\bar{Φ}}_{\dot{B} 1} (1))}^{q}} \land {{({\bar{Φ}}_{\dot{B} 2} (o))}^{q} \land {({\bar{Φ}}_{\dot{B} 2} (1))}^{q}} \\ = & {{({\bar{Φ}}_{\dot{B} 1} (o))}^{q} \land {({\bar{Φ}}_{\dot{B} 2} (o))}^{q}} \land {{({\bar{Φ}}_{\dot{B} 1} (1))}^{q} \land {({\bar{Φ}}_{\dot{B} 2} (1))}^{q}} \\ = & {{({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o^{- 1}))}^{q} \land {({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (1))}^{q}} \\ {({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o^{- 1}))}^{q} & \geq & {{({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o))}^{q} \land {({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (1))}^{q}} = {({\bar{Φ}}_{(\dot{B} 1 \cap \dot{B} 2)} (o))}^{q}, \end{matrix}

for all

o \in F / {0} .

Hence, this conclude the proof that

{\dot{B}}_{1} \cap {\dot{B}}_{2}

is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

. □

Theorem 7.

Let

\dot{B} = {ϱ, Φ_{\dot{B}} (ϱ), {\bar{Φ}}_{\dot{B}} (ϱ)}

be a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

. Then,

{(Φ_{E} (ϱ^{m}))}^{q} \geq {(Φ_{\dot{B}} (ϱ))}^{q} and {({\bar{Φ}}_{\dot{B}} (ϱ^{m}))}^{q} \leq ({\bar{Φ}}_{\dot{B}} {(ϱ)}^{q})

for all

ϱ \in F

and

m \in N .

Proof.

We employ the mathematical induction technique to demonstrate this theorem. Let

u \in F

; then,

{(Φ_{\dot{B}} (ϱ - ϑ) (ϱ - ϑ))}^{q} = {(Φ_{\dot{B}} (ϱ - ϑ) (ϱ - ϑ))}^{q} \geq {{(Φ_{\dot{B}} (ϱ - ϑ))}^{q} \land {(Φ_{\dot{B}} (ϱ - ϑ))}^{q}} = {(Φ_{\dot{B}} (ϱ - ϑ))}^{q}

. As a result, the inequality is true for

m = 2

. Assume that the inequality holds for

m = n - 1

; we have

{(Φ_{\dot{B}} {(ϱ - ϑ)}^{n - 1})}^{q} \geq {(Φ_{\dot{B}} (ϱ - ϑ))}^{q}

. Then,

{(Φ_{\dot{B}} {(ϱ - ϑ)}^{n})}^{q} = {(Φ_{\dot{B}} {(ϱ - ϑ)}^{n - 1} (ϱ - ϑ))}^{q} \geq {{(Φ_{\dot{B}} (ϱ - ϑ))}^{q} \land {(Φ_{\dot{B}} {(ϱ - ϑ)}^{n - 1})}^{q}} = {(Φ_{\dot{B}} (ϱ - ϑ))}^{q}

. From mathematical induction, we have

{(Φ_{\dot{B}} {(ϱ - ϑ)}^{m})}^{q} \geq {{(Φ_{\dot{B}} (ϱ - ϑ))}^{q}}

for all

m \in N .

In a similar fashion,

{({\bar{Φ}}_{\dot{B}} {(ϱ - ϑ)}^{2})}^{q} = {({\bar{Φ}}_{\dot{B}} (ϱ - ϑ) (ϱ - ϑ))}^{q} \leq {{({\bar{Φ}}_{\dot{B}} (ϱ - ϑ))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (ϱ - ϑ))}^{q}} = {({\bar{Φ}}_{\dot{B}} (ϱ - ϑ))}^{q}

. The result holds for

m = 2

; so, we suggest that it holds true for

m = n - 1

such that

{({\bar{Φ}}_{\dot{B}} (ϱ^{n - 1}))}^{q} \leq {({\bar{Φ}}_{\dot{B}} (ϱ))}^{q}

. Then,

{({\bar{Φ}}_{\dot{B}} (ϱ^{n}))}^{q} = {({\bar{Φ}}_{\dot{B}} (ϱ^{n - 1} i))}^{q} \leq {{({\bar{Φ}}_{\dot{B}} (ϱ))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (ϱ^{n - 1}))}^{q}} = {({\bar{Φ}}_{\dot{B}} (ϱ))}^{q}

. Now, we conclude this result

{({\bar{Φ}}_{\dot{B}} (ϱ^{m}))}^{q} \leq {({\bar{Φ}}_{\dot{B}} (ϱ))}^{q}

for all

m \in N .

Moreover,

{(Φ_{\dot{B}} (ϱ^{n - 1}))}^{q} \geq {(Φ_{\dot{B}} (ϱ))}^{q}

. Then,

{(Φ_{\dot{B}} (ϱ^{n}))}^{q} = {(Φ_{\dot{B}} (ϱ^{n - 1} ϱ))}^{q} \geq {{(Φ_{\dot{B}} (ϱ))}^{q} \land {(Φ_{\dot{B}} (ϱ^{n - 1}))}^{q}} = {(Φ_{\dot{B}} (ϱ))}^{q}

. Now, we have

{(Φ_{\dot{B}} (ϱ^{m}))}^{q} \geq {{(Φ_{\dot{B}} (ϱ))}^{q}}

for all

m \in N .

Similarly, we obtain

{({\bar{Φ}}_{\dot{B}} (ϱ^{2}))}^{q} = {({\bar{Φ}}_{\dot{B}} (ϱ ϱ))}^{q} \leq {{({\bar{Φ}}_{\dot{B}} (ϱ))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (ϱ))}^{q}} = {({\bar{Φ}}_{\dot{B}} (ϱ))}^{q}

. In the same fashion, we obtain the following result:

{({\bar{Φ}}_{\dot{B}} (ϱ^{n - 1}))}^{q} \leq {({\bar{Φ}}_{\dot{B}} (ϱ))}^{q}

. Then,

{({\bar{Φ}}_{\dot{B}} (ϱ^{n}))}^{q} = {({\bar{Φ}}_{\dot{B}} (ϱ^{n - 1} ϱ))}^{q} \leq {{({\bar{Φ}}_{\dot{B}} (ϱ))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (ϱ^{n - 1}))}^{q}} = {({\bar{Φ}}_{\dot{B}} (ϱ))}^{q}

. By using mathematical induction, we have

{({\bar{Φ}}_{\dot{B}} (ϱ^{m}))}^{q} \leq {({\bar{Φ}}_{\dot{B}} (ϱ))}^{q}

for all

m \in N .

□

Theorem 8.

Let

\dot{B} = {(r, Φ_{\dot{B}} (r), {\bar{Φ}}_{\dot{B}} (r)) : r \in F}

be a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

. If

Φ_{\dot{B}} (r_{1}) \neq Φ_{\dot{B}} (r_{2})

and

{\bar{Φ}}_{\dot{B}} (r_{1}) \neq {\bar{Φ}}_{\dot{B}} (r_{2})

for some

i_{1}, r_{2} \in F

, then

{(Φ_{\dot{B}} (r_{1} - r_{2}))}^{q} = {(Φ_{\dot{B}} (r_{1}))}^{q} \land {(Φ_{\dot{B}} (r_{2}))}^{q}

and

{({\bar{Φ}}_{\dot{B}} (r_{1} - r_{2}))}^{q} = {({\bar{Φ}}_{\dot{B}} (r_{1}))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (r_{2}))}^{q}

.

Proof.

To obtain the desired result, we take arbitrary entities

r_{1}, r_{2} \in F

as

Φ_{\dot{B}} (r_{1}) > Φ_{\dot{B}} (r_{2})

; then, obviously,

{(Φ_{\dot{B}} (r_{1}))}^{q} > {(Φ_{\dot{B}} (r_{2}))}^{q}

. Consider

\begin{matrix} {(Φ_{\dot{B}} (r_{2}))}^{q} & = & Φ_{\dot{B}} {(r_{1} - r_{1} + r_{2})}^{q} \\ \geq & {{(Φ_{\dot{B}} (- r_{1}))}^{q} \land {(Φ_{\dot{B}} (r_{1} + r_{2}))}^{q}} \\ = {{(Φ_{\dot{B}} (r_{1}))}^{q} \land {(Φ_{\dot{B}} (r_{1} + r_{2}))}^{q}} . \end{matrix}

(5)

Since

{(Φ_{\dot{B}} (r_{1}))}^{q} > {(Φ_{\dot{B}} (r_{2}))}^{q}

, we conclude from Equation (5) that

\begin{matrix} {(Φ_{\dot{B}} (r_{2}))}^{q} & \geq & {(Φ_{\dot{B}} (r_{1} + r_{2}))}^{q} \end{matrix}

(6)

\begin{matrix} also, {(Φ_{\dot{B}} (r_{1} - r_{2}))}^{q} & \geq & {{(Φ_{\dot{B}} (r_{1}))}^{q} \land {(Φ_{\dot{B}} (r_{2}))}^{q}} \\ = & {(Φ_{\dot{B}} (r_{2}))}^{q} \end{matrix}

(7)

\begin{matrix} thus, {(Φ_{\dot{B}} (r_{1} + r_{2}))}^{q} & \geq & {(Φ_{\dot{B}} (r_{2}))}^{q} \end{matrix}

(8)

by Equations (6) and (8), we obtain

\begin{matrix} {(Φ_{\dot{B}} (r_{1} - r_{2}))}^{q} = {(Φ_{K} (r_{2}))}^{q} = {{(Φ_{\dot{B}} (r_{1}))}^{q} \land {(Φ_{\dot{B}} (r_{2}))}^{q}} . \end{matrix}

(9)

Moreover, we obtain the results if

{\bar{Φ}}_{\dot{B}} (r_{1}) > {\bar{Φ}}_{\dot{B}} (r_{2})

.

\begin{matrix} Suppose, {({\bar{Φ}}_{\dot{B}} (r_{2}))}^{q} & = & {\bar{Φ}}_{\dot{B}} {(r_{1} - r_{1} + r_{2})}^{q} \\ \leq & {{({\bar{Φ}}_{\dot{B}} (- r_{1}))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (r_{1} + r_{2}))}^{q}} \\ = {{({\bar{Φ}}_{\dot{B}} (r_{1}))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (r_{1} + r_{2}))}^{q}} . \end{matrix}

(10)

Since

{({\bar{Φ}}_{\dot{B}} (r_{1}))}^{q} > {({\bar{Φ}}_{\dot{B}} (r_{2}))}^{q}

, from Equation (10), we have

\begin{matrix} {({\bar{Φ}}_{\dot{B}} (r_{2}))}^{q} \leq {({\bar{Φ}}_{\dot{B}} (r_{1} + r_{2}))}^{q} \\ also, {({\bar{Φ}}_{\dot{B}} (r_{1} - r_{2}))}^{q} & \leq & {{({\bar{Φ}}_{\dot{B}} (r_{1}))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (r_{2}))}^{q}} = {({\bar{Φ}}_{\dot{B}} (r_{2}))}^{q} that is \end{matrix}

(11)

\begin{matrix} {({\bar{Φ}}_{\dot{B}} (r_{1} + r_{2}))}^{q} \leq {({\bar{Φ}}_{\dot{B}} (r_{2}))}^{q} \end{matrix}

(12)

by Equations (11) and (12) we obtain

\begin{matrix} {({\bar{Φ}}_{\dot{B}} (r_{1} - r_{2}))}^{q} & = & {({\bar{Φ}}_{\dot{B}} (r_{2}))}^{q} = {{({\bar{Φ}}_{\dot{B}} (r_{1}))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (r_{2}))}^{q}} . \end{matrix}

□

Theorem 9.

Let

B = {(ϱ, Φ_{\dot{B}} (ϱ), {\bar{Φ}}_{K} (ϱ)) : ϱ \in F}

be a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of field

(F, +, .)

. Then,

1.: ${(Φ_{\dot{B}} (ϱ - r))}^{q} = {(Φ_{\dot{B}} (0))}^{q}$ , and then, ${(Φ_{\dot{B}} (ϱ))}^{q} = {(Φ_{\dot{B}} (r))}^{q}$ for all $ϱ, r \in F$ .
2.: If ${(Φ_{\dot{B}} (ϱ r^{- 1}))}^{q} = {(Φ_{\dot{B}} (1))}^{q}$ , then ${(Φ_{\dot{B}} (ϱ))}^{q} = {(Φ_{\dot{B}} (r))}^{q} f o r a l l ϱ, r \in F / {0}$ .

Proof.

Let

ϱ

and

r

be in

F

.

Suppose that $ϱ, r \in F$ ; then,

$\begin{matrix} {(Φ_{\dot{B}} (ϱ))}^{q} = {(Φ_{\dot{B}} (ϱ - r + r))}^{q} & \geq & {{(Φ_{\dot{B}} (ϱ - r))}^{q} \land {(Φ_{\dot{B}} (r))}^{q}} \\ = & {{(Φ_{\dot{B}} (0))}^{q} \land {(Φ_{\dot{B}} (r))}^{q}} \\ = & {(Φ_{\dot{B}} (r))}^{q} \\ = & {(Φ_{\dot{B}} (- r))}^{q} \\ = & {(Φ_{\dot{B}} (ϱ - ϱ - r))}^{q} \\ \geq & {{(Φ_{\dot{B}} (ϱ - r))}^{q} \land {(Φ_{\dot{B}} (- ϱ))}^{q}} \\ = & {{(Φ_{\dot{B}} (0))}^{q} \land {(Φ_{\dot{B}} (- ϱ))}^{q}} \\ = & {(Φ_{\dot{B}} (- ϱ))}^{q} \\ = & {(Φ_{\dot{B}} (ϱ))}^{q} \end{matrix}$

Therefore, ${(Φ_{\dot{B}} (ϱ))}^{q} = {(Φ_{\dot{B}} (r))}^{q} for all ϱ, r \in F$ .
In the same fashion,

$\begin{matrix} {({\bar{Φ}}_{\dot{B}} (ϱ))}^{q} = {({\bar{Φ}}_{\dot{B}} (ϱ - r + r))}^{q} & \leq & {{({\bar{Φ}}_{\dot{B}} (ϱ - r))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (r))}^{q}} \\ = & {{({\bar{Φ}}_{\dot{B}} (0))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (r))}^{q}} \\ = & {({\bar{Φ}}_{\dot{B}} (r))}^{q} \\ = & {({\bar{Φ}}_{\dot{B}} (- r))}^{q} \\ = & {({\bar{Φ}}_{\dot{B}} (ϱ - i - r))}^{q} \\ \leq & {{({\bar{Φ}}_{\dot{B}} (ϱ - r))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (- ϱ))}^{q}} \\ = & {{({\bar{Φ}}_{\dot{B}} (0))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (- ϱ))}^{q}} \\ = & {({\bar{Φ}}_{\dot{B}} (ϱ))}^{q} \end{matrix}$

$Therefore, {({\bar{Φ}}_{\dot{B}} (ϱ))}^{q} = {({\bar{Φ}}_{\dot{B}} (r))}^{q} for all ϱ, r \in F .$
Moreover,

$\begin{matrix} {(Φ_{\dot{B}} (ϱ))}^{q} & = & {(Φ_{\dot{B}} (ϱ r^{- 1} r))}^{q} \\ \geq & {{(Φ_{\dot{B}} (ϱ r^{- 1}))}^{q} \land {(Φ_{\dot{B}} (r))}^{q}} \\ \geq & {{(Φ_{\dot{B}} (1))}^{q} \land {(Φ_{\dot{B}} (r))}^{q}} \\ = & {(Φ_{\dot{B}} (r))}^{q} \end{matrix}$

$\begin{matrix} = & {(Φ_{\dot{B}} (r^{- 1}))}^{q} \\ = & {(Φ_{\dot{B}} (ϱ r^{- 1} i^{- 1}))}^{q} \\ \geq & {{(Φ_{\dot{B}} (ϱ r^{- 1}))}^{q} \land {(Φ_{\dot{B}} (ϱ^{- 1}))}^{q}} \\ \geq & {{(Φ_{\dot{B}} (1))}^{q} \land {(Φ_{\dot{B}} (ϱ^{- 1}))}^{q}} \\ = & {(Φ_{\dot{B}} (ϱ))}^{q} \end{matrix}$

Therefore, ${(Φ_{\dot{B}} (ϱ))}^{q} = {(Φ_{\dot{B}} (r))}^{q} for all ϱ, r \neq 0 \in F$ .
In similarly way,

$\begin{matrix} {({\bar{Φ}}_{\dot{B}} (ϱ))}^{q} & = & {({\bar{Φ}}_{\dot{B}} (ϱ r^{- 1} r))}^{q} \\ \leq & {{({\bar{Φ}}_{\dot{B}} (ϱ v^{- 1}))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (r))}^{q}} \\ \leq & {{({\bar{Φ}}_{\dot{B}} (1))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (r))}^{q}} \\ = & {({\bar{Φ}}_{\dot{B}} (r))}^{q} \\ = & {({\bar{Φ}}_{\dot{B}} (r^{- 1}))}^{q} \\ = & {({\bar{Φ}}_{\dot{B}} (ϱ r^{- 1} i^{- 1}))}^{q} \\ \leq & {{({\bar{Φ}}_{\dot{B}} (ϱ r^{- 1}))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (ϱ^{- 1}))}^{q}} \\ \leq & {{({\bar{Φ}}_{\dot{B}} (1))}^{q} \lor {({\bar{Φ}}_{\dot{B}} (ϱ^{- 1}))}^{q}} \\ = & {({\bar{Φ}}_{\dot{B}} (ϱ))}^{q} \end{matrix}$

$Therefore, {({\bar{Φ}}_{\dot{B}} (ϱ))}^{q} = {({\bar{Φ}}_{\dot{B}} (r))}^{q} for all ϱ, r \neq 0 \in F .$ Hence, this illustrates the proof.

□

Theorem 10.

Let 0 and e represent the identity element of

F

with respect to addition and multiplication, respectively, and

E = {i, Φ_{E} (i), {\bar{Φ}}_{E} (i)}

be a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

. Therefore,

1.: If ${(Φ_{E} (i_{1}))}^{q} = {(Φ_{E} (0))}^{q}$ for some $i_{1} \in F$ , then ${(Φ_{E} (i_{1} - i_{2}))}^{q} = {(Φ_{E} (i_{2}))}^{q}$ for all $i_{2} \in F$ ;
2.: If ${({\bar{Φ}}_{E} (i_{1}))}^{q} = {({\bar{Φ}}_{E} (0))}^{q}$ for some $i_{1} \in F$ , then ${({\bar{Φ}}_{E} (i_{1} - i_{2}))}^{q} = {({\bar{Φ}}_{E} (i_{2}))}^{q}$ for all $i_{2} \in F$ ;
3.: If ${(Φ_{E} (i_{1}))}^{q} = {(Φ_{E} (1))}^{q}$ for some $i_{1} \in F$ , then ${(Φ_{E} (i_{1} i_{2}))}^{q} = {(Φ_{E} (1))}^{q}$ , for all $i_{2} \in F$ ;
4.: If ${({\bar{Φ}}_{E} (i_{1}))}^{q} = {({\bar{Φ}}_{E} (1))}^{q}$ for some $i_{1} \in F$ , then ${({\bar{Φ}}_{E} (i_{1} i_{2}))}^{q} = {({\bar{Φ}}_{E} (1))}^{q}$ for all $i_{2} \in F .$

Proof.

Assume that

E = {i, Φ_{E} (i), {\bar{Φ}}_{E} (i)}

is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

. We have

{(Φ_{E} (i_{1}))}^{q} = {(Φ_{E} (0))}^{q}

.

\begin{matrix} {(Φ_{E} (i_{2}))}^{q} & = & Φ_{E} {(i_{1} - i_{1} + i_{2})}^{q} \\ \geq & {{(Φ_{E} (- i_{1}))}^{q} \land {(Φ_{E} (i_{1} + i_{2}))}^{q}} \\ = & {{(Φ_{E} (- i_{1}))}^{q} \land {(Φ_{E} (i_{1} + i_{2}))}^{q}} \\ = {{(Φ_{E} (0))}^{q} \land {(Φ_{E} (i_{1} + i_{2}))}^{q}} . \end{matrix}

(13)

As

{(Φ_{E} (0))}^{q} \geq {(Φ_{E} (i_{2}))}^{q}

from Inequality (13), we obtain

\begin{matrix} {(Φ_{E} (i_{2}))}^{q} \geq Φ_{E} {(i_{1} - i_{2})}^{q} . \end{matrix}

(14)

Thus,

{(Φ_{E} (i_{1} - i_{2}))}^{q} \geq {{(Φ_{E} (i_{1}))}^{q} \land {(Φ_{E} (i_{2}))}^{q}} = {(Φ_{K} (i_{2}))}^{q}

. We have

\begin{matrix} {(Φ_{E} (i_{1} - i_{2}))}^{q} \geq {(Φ_{E} (i_{2}))}^{q} . \end{matrix}

(15)

From Equations (14) and (15), we obtain

{(Φ_{E} (i_{1} - i_{2}))}^{q} = {(Φ_{E} (i_{2}))}^{q} .

Now,

{({\bar{Φ}}_{E} (i_{1}))}^{q} = {({\bar{Φ}}_{E} (0))}^{q} .

\begin{matrix} {({\bar{Φ}}_{E} (i_{2}))}^{q} & = & {\bar{Φ}}_{E} {(i_{1} - i_{1} + i_{2})}^{q} \\ \leq & {{({\bar{Φ}}_{E} (- i_{1}))}^{q} \lor {({\bar{Φ}}_{E} (i_{1} + i_{2}))}^{q}} \\ = & {{(Φ_{E} (- i_{1}))}^{q} \lor {(Φ_{E} (i_{1} + i_{2}))}^{q}} \\ = {{(Φ_{E} (0))}^{q} \lor {(Φ_{E} (i_{1} + i_{2}))}^{q}} . \end{matrix}

(16)

Because

{({\bar{Φ}}_{E} (0))}^{q} \leq {({\bar{Φ}}_{E} (i_{2}))}^{q}

form the Inequality (16), we have

\begin{matrix} {({\bar{Φ}}_{E} (i_{2}))}^{q} \leq {\bar{Φ}}_{E} {(i_{1} - i_{2})}^{q} . \end{matrix}

(17)

Thus,

{({\bar{Φ}}_{E} (i_{1} - i_{2}))}^{q} \leq {{({\bar{Φ}}_{E} (i_{1}))}^{q} \lor {({\bar{Φ}}_{E} (i_{2}))}^{q}} = {({\bar{Φ}}_{K} (i_{2}))}^{q}

; then, we have

\begin{matrix} {({\bar{Φ}}_{E} (i_{1} - i_{2}))}^{q} \leq {({\bar{Φ}}_{E} (i_{2}))}^{q} . \end{matrix}

(18)

From Equations (17) and (18), we have

{({\bar{Φ}}_{E} (i_{1} - i_{2}))}^{q} = {({\bar{Φ}}_{E} (i_{2}))}^{q} .

\begin{matrix} {(Φ_{E} (i_{2}))}^{q} & = & Φ_{E} {(i_{1}^{- 1} i_{1} i_{2})}^{q} \\ \geq & {{(Φ_{E} (i_{1}^{- 1}))}^{q} \land {(Φ_{E} (i_{1} i_{2}))}^{q}} \\ = & {{(Φ_{E} (i_{1}))}^{q} \land {(Φ_{E} (i_{1} i_{2}))}^{q}} \\ = {{(Φ_{E} (1))}^{q} \land {(Φ_{E} (i_{1} i_{2}))}^{q}} . \end{matrix}

(19)

As

{(Φ_{E} (1))}^{q} \geq {(Φ_{E} (i_{2}))}^{q}

from the Inequality (19), we conclude that

\begin{matrix} {(Φ_{E} (i_{2}))}^{q} \geq Φ_{E} {(i_{1} i_{2})}^{q} . \end{matrix}

(20)

Thus,

{(Φ_{E} (i_{1} i_{2}))}^{q} \geq {{(Φ_{E} (i_{1}))}^{q} \land {(Φ_{E} (i_{2}))}^{q}} = {(Φ_{K} (i_{2}))}^{q}

. We have

\begin{matrix} {(Φ_{E} (i_{1} i_{2}))}^{q} \geq {(Φ_{E} (i_{2}))}^{q} . \end{matrix}

(21)

From Equations (20) and (21), we obtain

{(Φ_{E} (i_{1} i_{2}))}^{q} = {(Φ_{E} (i_{2}))}^{q} .

□

Theorem 11.

Suppose that 0 and 1 represent additive and multiplicative identity elements of

F

, respectively, and

E = {i, Φ_{E} (i), {\bar{Φ}}_{\dot{E}} (i)}

is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F

. Then,

Q = {i \in F : {(Φ_{\dot{E}} (i))}^{q} = {(Φ_{\dot{E}} (0))}^{q} and {({\bar{Φ}}_{\dot{E}} (i))}^{q} = {({\bar{Φ}}_{\dot{E}} (0))}^{q}}

is a subfield of

F

.

Proof.

We know that

0, 1 \in Q

, so

Q

is a non-empty subset of

F

. Suppose

i_{1}, i_{2} \in Q

. Then,

\begin{matrix} {(Φ_{\dot{E}} (i_{1} - i_{2}))}^{q} & \geq & {{(Φ_{\dot{E}} (i_{1}))}^{q} \land {(Φ_{\dot{E}} (i_{1}))}^{q}} \\ = & {{(Φ_{\dot{E}} (i_{1}))}^{q} \land {(Φ_{E} (i_{2}))}^{q}} \\ = & {{(Φ_{\dot{E}} (0))}^{q} \land {(Φ_{E} (0))}^{q}} \\ = & {(Φ_{\dot{E}} (0))}^{q} . \end{matrix}

From Theorem 1, we have

{(Φ_{\dot{E}} (0))}^{q} \geq {(Φ_{\dot{E}} (i_{1} - i_{2}))}^{q}

. Then, obviously, we have

{(Φ_{\dot{E}} (0))}^{q} = {(Φ_{\dot{E}} (i_{1} - i_{2}))}^{q}

. Now, we show that

{({\bar{Φ}}_{\dot{E}} (0))}^{q} = {({\bar{Φ}}_{\dot{E}} (i_{1} - i_{2}))}^{q}

for

\begin{matrix} {({\bar{Φ}}_{\dot{E}} (i_{1} - i_{2}))}^{q} & \leq & {{({\bar{Φ}}_{\dot{E}} (i_{1}))}^{q} \lor {({\bar{Φ}}_{\dot{E}} (i_{1}))}^{q}} \\ = & [{({\bar{Φ}}_{\dot{E}} (i_{1}))}^{q} \lor {({\bar{Φ}}_{E} (i_{2}))}^{q}] \\ = & [{({\bar{Φ}}_{\dot{E}} (0))}^{q} \lor {({\bar{Φ}}_{E} (0))}^{q}] \\ = & {({\bar{Φ}}_{\dot{E}} (0))}^{q} . \end{matrix}

Then, it is clear that

{({\bar{Φ}}_{\dot{E}} (0))}^{q} = {({\bar{Φ}}_{\dot{E}} (i_{1} - i_{2}))}^{q}

.

Furthermore,

\begin{matrix} {(Φ_{\dot{E}} (i_{1} i_{2}^{- 1}))}^{q} & \geq & {{(Φ_{\dot{E}} (i_{1}))}^{q} \land {(Φ_{\dot{E}} (i_{2}^{- 1}))}^{q}} \\ \geq & {{(Φ_{\dot{E}} (i_{1}))}^{q} \land {(Φ_{\dot{E}} (i_{2}))}^{q}} \\ = & {{(Φ_{\dot{E}} (1))}^{q} \land {(Φ_{E} (1))}^{q}} \\ = & {(Φ_{\dot{E}} (1))}^{q} . \end{matrix}

In a similar fashion,

\begin{matrix} {({\bar{Φ}}_{\dot{E}} (i_{1} i_{2}^{- 1}))}^{q} & \leq & {{({\bar{Φ}}_{\dot{E}} (i_{1}))}^{q} \lor {({\bar{Φ}}_{\dot{E}} (i_{2}^{- 1}))}^{q}} \\ \leq & {{({\bar{Φ}}_{\dot{E}} (i_{1}))}^{q} \lor {({\bar{Φ}}_{\dot{E}} (i_{2}))}^{q}} \\ = & {{({\bar{Φ}}_{\dot{E}} (1))}^{q} \lor {({\bar{Φ}}_{E} (1))}^{q}} \\ = & {({\bar{Φ}}_{\dot{E}} (1))}^{q} . \end{matrix}

From Theorem 1, we obviously establish

{(Φ_{\dot{E}} (i_{1} i_{2}^{- 1}))}^{q} = {(Φ_{\dot{E}} (1))}^{q} and {({\bar{Φ}}_{\dot{E}} (i_{1} i_{2}^{- 1}))}^{q} = {({\bar{Φ}}_{\dot{E}} (1))}^{q}}

for all

i_{1} - i_{2} \in F

. Hence, this concludes the proof. □

4. Homomorphism on q-Rung Orthopair Fuzzy Subfield

In this part, the impact of field homomorphism on the

q - \ddot{R} \ddot{O} \ddot{F}

subfield is investigated, which provides some fundamentally major findings under field homomorphism.

Theorem 12.

Suppose that

F_{1}

and

F_{2}

are two subfields. Let δ be a surjective homomorphism from

F_{1}

to

F_{2}

and

J = {\ddot{c_{1}}, Φ_{J} (\ddot{c_{1}}), {\bar{Φ}}_{J} (\ddot{c_{1}}) : \ddot{c_{1}} \in F_{1}}

is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F_{1}

. Then,

δ (J) = {\ddot{c_{2}}, Φ_{J} (\ddot{c_{2}}), {\bar{Φ}}_{J} (\ddot{c_{2}}) : \ddot{c_{2}} \in F_{2}}

is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F_{2}

.

Proof.

Let

δ : F_{1} \to F_{2}

be an onto homomorphism; then,

δ (F_{1}) = F_{2}

. Let

\ddot{c_{2}}, i_{2}

be entities of

F_{2}

. Suppose

i_{2} = δ (i_{1})

,

\ddot{c_{2}} = F (\ddot{c_{1}}), δ (i_{1} c_{1}) = δ (i_{1}) δ (\ddot{c_{1}}) = i_{2} c_{2}

and

δ (i_{1} - \ddot{c_{1}}) = δ (i_{1}) - δ (\ddot{c_{1}}) = i_{2} - \ddot{c_{2}}

.

\begin{matrix} {(Φ_{δ (J)} (i_{2} - \ddot{c_{2}}))}^{q} & = & {(\lor {Φ_{J} (z) : z \in F_{1}, δ (z) = (i_{2} - \ddot{c_{2}})})}^{q} \\ = & \lor {{(Φ_{J} (z))}^{q} : z \in F_{1}, δ (z) = (i_{2} - \ddot{c_{2}})} \\ = & \lor {{(Φ_{J} (i_{1} - \ddot{c_{1}}))}^{q} : z \in F_{1}, δ (i_{1}) = i_{2}, δ (\ddot{c_{1}}) = \ddot{c_{2}}, and δ (i_{1} - \ddot{c_{1}}) \\ = & δ (i_{1}) - δ (\ddot{c_{1}}) = i_{2} - \ddot{c_{2}}} . S i n c e δ i s a h o m o m o r p h i s m . \\ \geq & max {{{(Φ_{J} (i_{1}))}^{q} \land {(Φ_{J} (\ddot{c_{1}}))}^{q}} : i_{1}, \ddot{c_{1}} \in F_{1}, {δ (i_{1}) = i_{2}, δ (\ddot{c_{1}}) \\ = \ddot{c_{2}}}} . J is q - \ddot{R} \ddot{O} \ddot{F} subfield of F_{1} . \\ = & {max ({(Φ_{J} (i_{1}))}^{q} : i_{1} \in F_{1}, δ (i_{1}) = i_{2}) \land max ({(Φ_{J} (i_{2}))}^{q} : i_{1} \in F_{1}, \\ δ (i_{1}) = i_{2})} \\ = & {{(Φ_{δ (J)} (i_{2}))}^{q} \land {(Φ_{δ (J)} (\ddot{c_{2}}))}^{q}} \\ Therefore, {(Φ_{δ (J)} (i_{2} - \ddot{c_{2}}))}^{q} & \geq & {{(Φ_{δ (J)} (i_{2}))}^{q} \land {(Φ_{δ (J)} (\ddot{c_{2}}))}^{q}} for all i_{2}, \ddot{c_{2}} \in F_{2} . \\ {(Φ_{δ (J)} (i_{2} \ddot{c_{2}}))}^{q} & = & {(\lor {Φ_{J} (z) : z \in F_{1}, δ (z) = (i_{2} \ddot{c_{2}})})}^{q} \\ = & \lor {{(Φ_{J} (z))}^{q} : z \in F_{1}, δ (z) = (i_{2} \ddot{c_{2}})} \\ = & \lor {{(Φ_{J} (i_{1} \ddot{c_{1}}))}^{q} : z \in F_{1}, δ (i_{1}) = i_{2}, δ (\ddot{c_{1}}) = \ddot{c_{2}}, \\ and δ (i_{1} \ddot{c_{1}}) = δ (i_{1}) δ (\ddot{c_{1}}) = i_{2} \ddot{c_{2}}} . S i n c e δ i s a h o m o m o r p h i s m . \\ \geq & max {{{(Φ_{J} (i_{1}))}^{q} \land {(Φ_{J} (\ddot{c_{1}}))}^{q}} : i_{1}, \ddot{c_{1}} \in F_{1}, {δ (i_{1}) = i_{2}, δ (\ddot{c_{1}}) \\ = & \ddot{c_{2}}}} . J is q - \ddot{R} \ddot{O} \ddot{F} subfield of F_{1} . \\ = & {max ({(Φ_{J} (i_{1}))}^{q} : i_{1} \in F_{1}, δ (i_{1}) = i_{2}) \land max ({(Φ_{J} (i_{2}))}^{q} : i_{1} \in F_{1}, \\ δ (i_{1}) = i_{2})} \\ = & {{(Φ_{δ (J)} (i_{2}))}^{q} \land {(Φ_{δ (J)} (\ddot{c_{2}}))}^{q}} \end{matrix}

\begin{matrix} Therefore, {(Φ_{δ (J)} (i_{2} \ddot{c_{2}}))}^{q} & \geq & {{(Φ_{δ (J)} (i_{2}))}^{q} \land {(Φ_{δ (J)} (\ddot{c_{2}}))}^{q}} for all i_{2}, \ddot{c_{2}} \in F_{2} . \\ {(Φ_{δ (J)} (i_{2}^{- 1}))}^{q} & = & (Φ_{J} (z) | z \in F_{1}, \lor δ (z) = {(i_{2}^{- 1})}^{q} \\ = & (Φ_{J} (z^{- 1}) ∣ z^{- 1} \in F_{1}, \lor δ (z^{- 1}) = {(i_{2})}^{q} \\ = & (Φ_{δ (J)} {(i_{2})}^{q} \end{matrix}

In a similar fashion,

\begin{matrix} {({\bar{Φ}}_{δ (J)} (i_{2} - \ddot{c_{2}}))}^{q} & = & {(\land {{\bar{Φ}}_{J} (z) : z \in F_{1}, δ (z) = (i_{2} - \ddot{c_{2}})})}^{q} \\ = & \land {{({\bar{Φ}}_{J} (z))}^{q} : z \in F_{1}, δ (z) = (i_{2} - \ddot{c_{2}})} \\ = & \land {{({\bar{Φ}}_{J} (i_{1} - \ddot{c_{1}}))}^{q} : z \in F_{1}, δ (i_{1}) = i_{2}, δ (\ddot{c_{1}}) = \ddot{c_{2}}, \\ and δ (i_{1} - \ddot{c_{1}}) = δ (i_{1}) - δ (\ddot{c_{1}}) = i_{2} - \ddot{c_{2}}} . S i n c e δ i s a h o m o m o r p h i s m . \end{matrix}

\begin{matrix} \leq & max {{{({\bar{Φ}}_{J} (i_{1}))}^{q} \lor {({\bar{Φ}}_{J} (\ddot{c_{1}}))}^{q}} : i_{1}, \ddot{c_{1}} \in F_{1}, {δ (i_{1}) = i_{2}, δ (\ddot{c_{1}}) = \ddot{c_{2}}}} . \\ J is q - \ddot{R} \ddot{O} \ddot{F} subfield of F_{1} . \\ = & {min ({({\bar{Φ}}_{J} (i_{1}))}^{q} : i_{1} \in F_{1}, δ (i_{1}) = i_{2}) \lor min ({({\bar{Φ}}_{J} (i_{2}))}^{q} : i_{1} \in F_{1}, \\ δ (i_{1}) = i_{2})} \\ = & {{({\bar{Φ}}_{δ (J)} (i_{2}))}^{q} \lor {({\bar{Φ}}_{δ (J)} (\ddot{c_{2}}))}^{q}} So, \\ {({\bar{Φ}}_{δ (J)} (i_{2} - \ddot{c_{2}}))}^{q} & \leq & {{({\bar{Φ}}_{δ (J)} (i_{2}))}^{q} \lor {({\bar{Φ}}_{δ (J)} (\ddot{c_{2}}))}^{q}} for all i_{2}, \ddot{c_{2}} \in F_{2} . \\ {({\bar{Φ}}_{δ (J)} (i_{2} \ddot{c_{2}}))}^{q} & = & {(\land {{\bar{Φ}}_{J} (z) : z \in F_{1}, δ (z) = (i_{2} \ddot{c_{2}})})}^{q} \\ = & \land {{({\bar{Φ}}_{J} (z))}^{q} : z \in F_{1}, δ (z) = (i_{2} \ddot{c_{2}})} \\ = & \land {{({\bar{Φ}}_{J} (i_{1} \ddot{c_{1}}))}^{q} : z \in F_{1}, δ (i_{1}) = i_{2}, δ (\ddot{c_{1}}) = \ddot{c_{2}}, \\ and δ (i_{1} \ddot{c_{1}}) = δ (i_{1}) δ (\ddot{c_{1}}) = i_{2} \ddot{c_{2}}} . ∵ δ is a homomorphism . \end{matrix}

\begin{matrix} \leq & max {{{({\bar{Φ}}_{J} (i_{1}))}^{q} \lor {({\bar{Φ}}_{J} (\ddot{c_{1}}))}^{q}} : i_{1}, \ddot{c_{1}} \in F_{1}, {δ (i_{1}) = i_{2}, δ (\ddot{c_{1}}) = \ddot{c_{2}}}} . \\ J is q - \ddot{R} \ddot{O} \ddot{F} subfield of F_{1} . So, \\ = & {min ({({\bar{Φ}}_{J} (i_{1}))}^{q} : i_{1} \in F_{1}, δ (i_{1}) = i_{2}) \lor min ({({\bar{Φ}}_{J} (i_{2}))}^{q} : i_{1} \in F_{1}, \\ δ (i_{1}) = i_{2})} \\ = & {{({\bar{Φ}}_{δ (J)} (i_{2}))}^{q} \lor {({\bar{Φ}}_{δ (J)} (\ddot{c_{2}}))}^{q}} \\ {({\bar{Φ}}_{δ (J)} (i_{2} \ddot{c_{2}}))}^{q} & \leq & {{({\bar{Φ}}_{δ (J)} (i_{2}))}^{q} \lor {({\bar{Φ}}_{δ (J)} (\ddot{c_{2}}))}^{q}} for all i_{2}, \ddot{c_{2}} \in F_{2} . \end{matrix}

\begin{matrix} And, {({\bar{Φ}}_{δ (J)} (i_{2}^{- 1}))}^{q} & = & ({\bar{Φ}}_{J} (z) | z \in F_{1}, \lor δ (z) = {(i_{2}^{- 1})}^{q} \\ = & ({\bar{Φ}}_{J} (z^{- 1}) ∣ z^{- 1} \in F_{1}, \lor δ (z^{- 1}) = {(i_{2})}^{q} \\ = & ({\bar{Φ}}_{δ (J)} {(i_{2})}^{q} \end{matrix}

δ (J) = {\ddot{c_{2}}, Φ_{J} (\ddot{c_{2}}), {\bar{Φ}}_{J} (\ddot{c_{2}}) : \ddot{c_{2}} \in F}

is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F_{2}

. □

Theorem 13.

Let

δ : F_{1} \to F_{2}

is a bijective homomorphism and

T = {\ddot{c_{2}}, Φ_{T} (\ddot{c_{2}}), {\bar{Φ}}_{T} (\ddot{c_{2}}) : \ddot{c_{2}} \in F_{2}}

is a

q - \ddot{R} \ddot{O} \ddot{F}

subring of

F_{2}

such that

δ^{- 1} (J) = {\ddot{c_{1}}, Φ_{δ^{- 1} T} (\ddot{c_{1}}), {\bar{Φ}}_{δ^{- 1} T} (\ddot{c_{1}}) : \ddot{c_{1}} \in F_{1}}

is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F_{1} .

Proof.

Consider

i_{1}, \ddot{c_{1}} \in F_{1}

, then

i_{2}, \ddot{c_{2}} \in F_{2}

. Now,

\begin{matrix} Φ_{δ^{- 1} (T)} (i_{1} - \ddot{c_{1}}))^{q} & = & {(Φ_{(T)} δ (i_{1} - \ddot{c_{1}}))}^{q} \\ = & {(Φ_{(T)} δ (i_{1}) - δ (\ddot{c_{1}}))}^{q} . ∵ δ is homomorphism . \\ \geq & {{(Φ_{T} (i_{1}))}^{q} \land {(Φ_{T} (\ddot{c_{1}}))}^{q}} (T is q - \ddot{R} \ddot{O} \ddot{F} subfield of F_{2}) . \\ \geq & {{Φ_{δ^{- 1} (T)} (i_{1}))}^{q} \land Φ_{δ^{- 1} (T)} (\ddot{c_{1}}))^{q}} . \end{matrix}

Similarly in case of non-membership,

\begin{matrix} {\bar{Φ}}_{δ^{- 1} (T)} (i_{1} - \ddot{c_{1}}))^{q} & = & {({\bar{Φ}}_{(T)} δ (i_{1} - \ddot{c_{1}}))}^{q} \\ = & {({\bar{Φ}}_{(T)} δ (i_{1}) δ (\ddot{c_{1}}))}^{q} . ∵ δ is homomorphism \\ \leq & {{({\bar{Φ}}_{T} (i_{1}))}^{q} \lor {({\bar{Φ}}_{T} (\ddot{c_{1}}))}^{q}} (T is q - \ddot{R} \ddot{O} \ddot{F} subfield of F_{2}) . \\ \leq & {{{\bar{Φ}}_{δ^{- 1} (T)} (i_{1}))}^{q} \lor {\bar{Φ}}_{δ^{- 1} (T)} (\ddot{c_{1}}))^{q}} \\ Φ_{δ^{- 1} (T)} (i_{1} \ddot{c_{1}}))^{q} & = & {(Φ_{(T)} δ (i_{1} \ddot{c_{1}}))}^{q} \\ = & {(Φ_{(T)} δ (i_{1}) δ (\ddot{c_{1}}))}^{q} . ∵ δ is homomorphism \\ \geq & {{(Φ_{T} (i_{1}))}^{q} \land {(Φ_{T} (\ddot{c_{1}}))}^{q}} (T is q - \ddot{R} \ddot{O} \ddot{F} subfield of F_{2}) . \\ \geq & {{Φ_{δ^{- 1} (T)} (i_{1}))}^{q} \land Φ_{δ^{- 1} (T)} (\ddot{c_{1}}))^{q}} . \end{matrix}

In other words,

\begin{matrix} {\bar{Φ}}_{δ^{- 1} (T)} (i_{1} \ddot{c_{1}}))^{q} & = & {({\bar{Φ}}_{(T)} δ (i_{1} \ddot{c_{1}}))}^{q} \\ = & {({\bar{Φ}}_{(T)} δ (i_{1}) δ (\ddot{c_{1}}))}^{q} . δ is homomorphism . \\ \leq & {{({\bar{Φ}}_{T} (i_{1}))}^{q} \lor {({\bar{Φ}}_{T} (\ddot{c_{1}}))}^{q}} . T is q - \ddot{R} \ddot{O} \ddot{F} subfield of F_{2} . \\ \leq & {{{\bar{Φ}}_{δ^{- 1} (T)} (i_{1}))}^{q} \lor {\bar{Φ}}_{δ^{- 1} (T)} (\ddot{c_{1}}))^{q}} . \end{matrix}

Let again

i_{1} \in F_{1}

then

\begin{matrix} {(Φ_{δ^{- 1} (J)} (i_{1}^{- 1}))}^{q} & = & (Φ_{J} {(δ (i_{1}^{- 1}))}^{q} \\ = & (Φ_{J} {(δ (i_{1}))}^{q} \\ = & {(Φ_{δ^{- 1} (J)} (i_{1}))}^{q} \end{matrix}

\begin{matrix} {({\bar{Φ}}_{δ^{- 1} (J)} (i_{1}^{- 1}))}^{q} & = & ({\bar{Φ}}_{J} {(δ (i_{1}^{- 1}))}^{q} \\ = & ({\bar{Φ}}_{J} {(δ (i_{1}))}^{q} \\ {({\bar{Φ}}_{δ^{- 1} (J)} (i_{1}^{- 1}))}^{q} & = & {({\bar{Φ}}_{δ^{- 1} (J)} (i_{1}))}^{q} \end{matrix}

□

Theorem 14.

If

δ : F_{1} \to F_{2}

is surjective homomorphism,

F_{1}

,

F_{2}

are two subfields and

J

be

q - \ddot{R} \ddot{O} \ddot{F}

ideal of

F_{1}

then

δ (A)

is

q - \ddot{R} \ddot{O} \ddot{F}

ideal of

F_{2}

.

Proof.

Suppose

A

be

q - \ddot{R} \ddot{O} \ddot{F}

ideal of

F_{1}

, then

{(Φ_{A} (i_{1} - \ddot{c_{1}}))}^{q} = {(Φ_{A} (\ddot{c_{1}} - i_{1}))}^{q}

and

{({\bar{Φ}}_{A} (i_{1} - \ddot{c_{1}}))}^{q} = {({\bar{Φ}}_{K} (\ddot{c_{1}} - i_{1}))}^{q}

for all

i_{1}, \ddot{c_{1}} \in F_{1}

. Let

i_{2}, \ddot{c_{2}} \in F_{2}

. Then there exist some elements

i_{1}, \ddot{c_{1}} \in F_{1}

for this

\ddot{c_{2}} = δ (\ddot{c_{1}}) a n d i_{2} = δ (i_{1})

. Then,

\begin{matrix} {(Φ_{δ (A)} (i_{2} - \ddot{c_{2}}))}^{q} & = & {{(Φ_{A} (z) | z \in F_{1} \lor δ (z) = (i_{2} - \ddot{c_{2}}))}^{q}} \\ = & {{((Φ_{A} (z)))}^{q} | z \in F_{1} \lor δ (z) = (i_{2} - \ddot{c_{2}})} \\ = & {{(Φ_{A} (i_{2} - \ddot{c_{2}}))}^{q} | z \in F_{1}, {δ (i_{1}) = i_{2}, δ (\ddot{c_{1}}) = \ddot{c_{2}}} \lor {δ (z) = \\ (i_{2} - \ddot{c_{2}}) and δ (i_{2} - \ddot{c_{2}}) = δ (i_{1}) - δ (\ddot{c_{1}}) = i_{2} - \ddot{c_{2}}}} \\ b e c a u s e δ i s a h o m o m o r p h i s m . \\ \geq & max {{{(Φ_{A} (i_{1}))}^{q} \land {(Φ_{A} (i_{2}))}^{q}} | i_{1}, \ddot{c_{1}} \in F_{1}, \\ {δ (i_{1}) = i_{2}, δ (\ddot{c_{1}}) = \ddot{c_{2}}}} \\ = & {max ({(Φ_{A} (i_{1}))}^{q} : i_{1} \in F_{1}, δ (i_{1}) = i_{2}) \land max ({(Φ_{A} (i_{2}))}^{q} : \\ i_{1} \in F_{1}, δ (i_{1}) = i_{2})} \\ = & {{(Φ_{δ (A)} (i_{2}))}^{q} \land {(Φ_{δ (A)} (\ddot{c_{2}}))}^{q}} . So, \\ {(Φ_{δ (A)} (i_{2} - \ddot{c_{2}}))}^{q} & \geq & {{(Φ_{δ (A)} (i_{2}))}^{q} \land {(Φ_{δ (A)} (\ddot{c_{2}}))}^{q}} for all i_{2}, \ddot{c_{2}} \in F_{2} . \\ {(Φ_{δ (A)} (i_{1} \ddot{c_{1}}))}^{q} & = & {{(Φ_{A} (z) | z \in F_{1} \lor δ (z) = (i_{1} \ddot{c_{1}}))}^{q}} \\ = & {{((Φ_{A} (z)))}^{q} | z \in F_{1} \lor δ (z) = (i_{1} \ddot{c_{1}})} \\ = & {{(Φ_{A} (i_{1} \ddot{c_{1}}))}^{q} | z \in F_{1}, {δ (i_{1}) = i_{2}, δ (\ddot{c_{1}}) = \ddot{c_{2}}} \lor {δ (z) = (i_{1} \ddot{c_{1}}) \\ and δ (i_{1} \ddot{c_{1}}) = δ (i_{1}) δ (\ddot{c_{1}}) = i_{2} \ddot{c_{2}}}} b e c a u s e δ i s a h o m o m o r p h i s m . \\ \geq & max {{{(Φ_{A} (i_{1}))}^{q} \land {(Φ_{A} (i_{2}))}^{q}} | i_{1}, \ddot{c_{1}} \in F_{1}, \\ {δ (i_{1}) = i_{2}, δ (\ddot{c_{1}}) = \ddot{c_{2}}}} \\ = & {max ({(Φ_{A} (i_{1}))}^{q} : i_{1} \in F_{1}, δ (i_{1}) = i_{2}) \land max ({(Φ_{A} (i_{2}))}^{q} : \\ i_{1} \in F_{1}, δ (i_{1}) = i_{2})} \\ = & {{(Φ_{δ (A)} (i_{2}))}^{q} \land {(Φ_{δ (A)} (\ddot{c_{2}}))}^{q}} . \\ Therefore, {(Φ_{δ (A)} (i_{1} \ddot{c_{1}}))}^{q} & \geq & {{(Φ_{δ (A)} (i_{2}))}^{q} \land {(Φ_{δ (A)} (\ddot{c_{2}}))}^{q}} for all i_{2}, \ddot{c_{2}} \in F_{2} . \\ {(Φ_{δ (A)} (i_{1}^{- 1}))}^{q} & = & (Φ_{A} (z) | z \in F_{1} \lor δ (z) = {(i_{1}^{- 1})}^{q} \\ = & (Φ_{A} {(δ (i_{1}))}^{q} \\ {({\bar{Φ}}_{δ (A)} (i_{1}^{- 1}))}^{q} & = & ({\bar{Φ}}_{A} (z) | z \in F_{1} \lor δ (z) = {(i_{1}^{- 1})}^{q} \\ = & ({\bar{Φ}}_{A} {(δ (i_{1}))}^{q} \end{matrix}

In the same way, we can show that

{({\bar{Φ}}_{δ (A)} (i_{2} - \ddot{c_{2}}))}^{q} \leq {{({\bar{Φ}}_{δ (A)} (i_{2}))}^{q} \lor {({\bar{Φ}}_{δ (A)} (\ddot{c_{2}}))}^{q}}

and

{({\bar{Φ}}_{δ (A)} (i_{1} \ddot{c_{1}}))}^{q} \leq {{({\bar{Φ}}_{δ (A)} (i_{2}))}^{q} \lor {({\bar{Φ}}_{δ (A)} (\ddot{c_{2}}))}^{q}} for all i_{2}, \ddot{c_{2}} \in F_{2} .

Hence, all the axiom of

q - \ddot{R} \ddot{O} \ddot{F}

ideal are hold. So,

δ (J)

is

q - \ddot{R} \ddot{O} \ddot{F}

ideal of

F_{2}

. □

Theorem 15.

Let

F_{1}

,

F_{2}

are two subfield. Let δ be bijective homomorphism

δ : F_{1} \to F_{2}

and

J = {o_{1}, Φ_{J} (o_{1}), {\bar{Φ}}_{J} (o_{1}) : o_{1} \in F_{1}}

be

q - \ddot{R} \ddot{O} \ddot{F}

ideal of

F_{2}

. Then

δ^{- 1} (J) = {o_{2}, Φ_{J} (o_{2}), {\bar{Φ}}_{J} (o_{2}) : o_{2} \in F_{1}}

is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F_{1}

.

Proof.

J

be

q - \ddot{R} \ddot{O} \ddot{F}

ideal of

F_{2}

then

{(Φ_{J} (r_{2} - o_{2}))}^{q} = {(Φ_{J} (o_{2} - r_{2}))}^{q}

and

{({\bar{Φ}}_{J} (r_{2} - o_{2}))}^{q} = {({\bar{Φ}}_{K} (o_{2} - r_{2}))}^{q}

for all

r_{2}, o_{2} \in F_{2}

. Suppose that

r_{1}, o_{1} \in F_{1}

.then there exist some elements

r_{1}, o_{1} \in F_{1}

for this

o_{2} = δ (o_{1}) a n d r_{2} = δ (r_{1})

. Let

o_{2}, r_{2}

be elements of

F_{2}

. Suppose

r_{2} = δ (r_{1})

,

o_{2} = F (o_{1}), δ (r_{1} o_{1}) = δ (r_{1}) δ (o_{1}) = r_{2} o_{2}

and

δ (r_{1} - o_{1}) = δ (r_{1}) - δ (o_{1}) = r_{2} - o_{2}

.

\begin{matrix} {(Φ_{δ^{- 1} (J)} (r_{1} - o_{1}))}^{q} & = & (δ^{- 1} (Φ_{J}) {((r_{1} - o_{1}))}^{q} \\ {(Φ_{δ^{- 1} (J)} (r_{1} - o_{1}))}^{q} & = & {(Φ_{J} (δ (r_{1} - o_{1})))}^{q} \\ = & {{(Φ_{J} (r_{1} - o_{1}))}^{q} | (r_{1} - o_{1}) \in F_{1}, {δ (r_{1}) = r_{2}, δ (o_{1}) = o_{2}} \lor \\ {δ (z) = (r_{1} - o_{1}) and δ (r_{1} - o_{1}) = δ (r_{1}) - δ (o_{1}) = r_{2} - o_{2}}} . \\ \geq & {max ({(Φ_{J} (r_{1}))}^{q} : r_{1} \in F_{1}, δ (r_{1}) = r_{2}) \land max ({(Φ_{J} (r_{2}))}^{q} : \\ r_{1} \in F_{1}, δ (r_{1}) = r_{2})} \\ = & {{(Φ_{δ (J)} (r_{2}))}^{q} \land {(Φ_{δ (J)} (o_{2}))}^{q}} . \\ So, {(Φ_{δ (J)} (r_{2} - o_{2}))}^{q} & \geq & {{(Φ_{δ (J)} (r_{2}))}^{q} \land {(Φ_{δ (J)} (o_{2}))}^{q}} for all r_{2}, o_{2} \in F_{2} . \end{matrix}

Similarly,

{({\bar{Φ}}_{δ (J)} (r_{2} - o_{2}))}^{q} \leq {{({\bar{Φ}}_{δ (J)} (r_{2}))}^{q} \lor {({\bar{Φ}}_{δ (J)} (o_{2}))}^{q}} for all r_{2}, o_{2} \in F_{2}

.

\begin{matrix} {(Φ_{δ^{- 1} (J)} (r_{1} o_{1}))}^{q} & = & (δ^{- 1} (Φ_{J}) {((r_{1} o_{1}))}^{q} \\ {(Φ_{δ^{- 1} (J)} (r_{1} o_{1}))}^{q} & = & {(Φ_{J} (δ (r_{1} o_{1})))}^{q} \\ = & {{(Φ_{J} (r_{1} o_{1}))}^{q} | (r_{1} o_{1}) \in F_{1}, {δ (r_{1}) = r_{2}, δ (o_{1}) = o_{2}} \lor {δ (z) = \\ (r_{1} o_{1}) and δ (r_{1} o_{1}) = δ (r_{1}) δ (o_{1}) = r_{2} o_{2}}} . ∵ δ i s a h o m o m o r p h i s m . \\ \geq & {max ({(Φ_{J} (r_{1}))}^{q} : r_{1} \in F_{1}, δ (r_{1}) = r_{2}) \land max ({(Φ_{J} (r_{2}))}^{q} : r_{1} \in F_{1}, \\ δ (r_{1}) = r_{2})} \\ = & {{(Φ_{δ (J)} (r_{2}))}^{q} \land {(Φ_{δ (J)} (o_{2}))}^{q}} . \\ So, {(Φ_{δ (J)} (r_{2} o_{2}))}^{q} & \geq & {{(Φ_{δ (J)} (r_{2}))}^{q} \land {(Φ_{δ (J)} (o_{2}))}^{q}} for all r_{2}, o_{2} \in F_{2} . \end{matrix}

Hence,

δ^{- 1} (J)

is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of

F_{1}

. □

5. Conclusions

The purpose of this article is to demonstrate the q-

\ddot{R} \ddot{O} \ddot{F}

subfield and its functions. The

q - \ddot{R} \ddot{O} \ddot{F}

subfield’s algebraic characteristics have been investigated. We created the necessary and adequate parameters for the

q - \ddot{R} \ddot{O} \ddot{F}

subfield. Every Pythagorean fuzzy subfield is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield of a certain field, and the intersection of two

q - \ddot{R} \ddot{O} \ddot{F}

subfields is a

q - \ddot{R} \ddot{O} \ddot{F}

subfield. Moreover, we discussed the consequence of homomorphism on the

q - \ddot{R} \ddot{O} \ddot{F}

subfield. For future work, we will focus on the complex q-rung orthopair fuzzy subfield and the lower level subset of the complex q-rung orthopair fuzzy subfield. Additionally, we intend to introduce the product of two complex q-rung orthopair fuzzy subfields, the novel idea of q-Rung orthopair fuzzy modules, and its vital attributes.

Author Contributions

K.A., M.H.M., A.A., E.-S.A.A.-T. and Q.X. developed the theory and performed the computations. K.A., M.H.M., A.A., E.-S.A.A.-T. and Q.X. verified the analytical methods. The published variant of the article has been read and approved by all authors. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Data Availability Statement

This study was not supported by any actual data. Anyone may utilise the hypothetical information used in this research by just citing this article.

Conflicts of Interest

No conflict of interest are disclosed by the authors.

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Alnefaie, K.; Xin, Q.; Almutlg, A.; Abo-Tabl, E.-S.A.; Mateen, M.H. A Novel Framework of q-Rung Orthopair Fuzzy Sets in Field. Symmetry 2023, 15, 114. https://doi.org/10.3390/sym15010114

AMA Style

Alnefaie K, Xin Q, Almutlg A, Abo-Tabl E-SA, Mateen MH. A Novel Framework of q-Rung Orthopair Fuzzy Sets in Field. Symmetry. 2023; 15(1):114. https://doi.org/10.3390/sym15010114

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Alnefaie, Kholood, Qin Xin, Ahmad Almutlg, El-Sayed A. Abo-Tabl, and M. Haris Mateen. 2023. "A Novel Framework of q-Rung Orthopair Fuzzy Sets in Field" Symmetry 15, no. 1: 114. https://doi.org/10.3390/sym15010114

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A Novel Framework of q-Rung Orthopair Fuzzy Sets in Field

Abstract

1. Introduction

2. Preliminaries

3. The q-Rung Orthopair Fuzzy Subfield

4. Homomorphism on q-Rung Orthopair Fuzzy Subfield

5. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Data Availability Statement

Conflicts of Interest

References

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