Definition 2.1. ^{[22, 23]}

Let (L, ∨, ˄, O, I) be a bounded lattice with an order-reversing involution ′, I and O the greatest and the smallest element of L respectively, and →: L × L ----→ L be a mapping. (L, ∨, ˄, ′, →, O, I) is called a lattice implication algebra (LIA) if the following conditions hold for any x, y, z ∈ L:

• (I₁) x → (y → z) = y → (x → z);

• (I₂) x → x = I;

• (I₃) x → y = y′→ x′;

• (I₄) x → y = y → x = I implies x = y;

• (I₅) (x → y) → y = (y → x) → x;

• (l₁) (x ∨ y) → z = (x → z) ˄ (y → z);

• (l₂) (x ˄ y) → z = (x → z) ∨ (y → z).

Definition 2.2. ^[23]

Let X be the set of propositional variables, (L, ∨, ˄, ′, →, O, I) be an LIA, T = L ∪ {′,→} be a type with ar(′) = 1, ar(→) = 2 and ar(a) = 0 for any a ∈ L. The proposition logic algebra of the lattice-valued proposition calculus on the set X of propositional variables (in short lattice-valued proposition logic system) is the free T algebra on X and denoted by LP(X).

Remark 2.1.

Note that LP(X) includes the constant formulae (a ∈L), which has been one of the key differences from the most existing many-valued logic systems, because, with the constant formulae included and the implication connective defined differently from the Kleene implication, the syntax in LP(X) is essentially not equivalent to the one in the classical logic any more.

Definition 2.3. ^[23]

The set Γ of formula of LP(X) is the least set Y satisfying the following conditions:

1. (1)

   X ⊆ Y;

2. (2)

   L ⊆Y;

3. (3)

   if p, q ∈ Y, then p′, p → q ∈ Y.

Note that the set of all the L-type fuzzy sets on Γ is denoted by ℱ_L(Γ). If A∈ ℱ_L(Γ), for any G∈Γ, A(G)∈L represents the membership degree of G in A.

Definition 2.4. ^[23]

A mapping γ: (LP(X), ′, →, O) → (L, ′, →, O) is called a valuation of LP(X), if it is a T-homomorphism.

If γ is a valuation of LP(X), we have γ (α) =α for any α∈L. The special element O denotes false in (LP(X), ′, →, O).

Definition 2.5. ^[25]

Let G ∈ Γ and α ∈ L. For any valuation γ of LP(X), if γ (G) ≤ α, we say G is always less than or equal to α (or G is α-false), denoted by G ≤ α.

Definition 2.6. ^[26]

Suppose V and F are the set of variable symbols and that of functional symbols in LF(X), respectively, the set of terms of LF(X) is defined as the smallest set 𝒥 satisfying the following conditions:

1. (1)

   V ⊆ 𝒥;

2. (2)

   For any n ∈ N, if f⁽ⁿ⁾ ∈ F, then for any t₁,…, t_n ∈ 𝒥, f⁽ⁿ⁾(t₁,…, t_n) ∈ 𝒥.

Remark 2.2.

f⁽⁰⁾ is specified as a constant symbol.

Definition 2.7. ^[26]

Suppose P is a predicate symbol set in LF(X). The set of atoms of LF(X) is defined as the smallest set 𝒜_t satisfying the following condition:

For any n ∈ N, if P⁽ⁿ⁾ ∈ P, then P⁽ⁿ⁾(t₀, t₁,…, t_n) ∈𝒜_t for any t₀, t₁,…, t_n ∈ 𝒥.

Remark 2.3.

P⁽⁰⁾ is specified as a certain element in L.

Definition 2.8. ^[26]

The set of formulas of LF(X) is defined as the smallest set ℱ satisfying the following conditions:

1. (1)

   𝒜_t ⊂ ℱ;

2. (2)

   If p, q ∈ ℱ, then p → q ∈ℱ ;

3. (3)

   If p ∈ ℱ and x is a free variable in p, then (∀x) p, (∃x) p ∈ ℱ.

Remark 2.4.

Note that p′ = p → O, p ∨ q = (p → q) → q, p ˄ q = (p′ ∨ q′)′, p ↔ q = (p → q) ˄ (q → p). Therefore, if p′, q ∈ ℱ, then p′, p ∨ q, p ˄ q, p ↔ q ∈ ℱ.

Definition 2.9. ^[26]

Suppose G ∈ ℱ, F_G is the set of all functional symbols occurring in G, P_G is the set of all predicate symbols occurring in G, and D (≠∅) is the domain of interpretations. An interpretation of G over D is a triple I_D = 〈D, µ_D, ν_D〉, where,

Definition 4.1. ^[26]

A formula G in lattice-valued first-order logic LF(X) is a generalized-literal, if it satisfies the following conditions:

1. (1)

   G is a literal; or

2. (2)

   G is constructed only by some literals and some implication connectives with the condition that G cannot be represented by connectives “∨” or “˄” and G cannot be decomposed into a simpler form (G is called an indecomposable implication form).

The disjunction of a finite number of generalized-literals is a generalized-clause. The conjunction of a finite number of generalized-clauses is a generalized-conjunctive normal form.

Definition 4.2. ^[26]

Let G ∈ℱ, α ∈ L. G is said to be α-false, if ν_D(G) ≤ α for any interpretation I_D = 〈D, µ_D, ν_D〉 of G.

Definition 4.3. ^[26]

Suppose G is a formula of the form Q₁x₁…Q_nx_nG^*, where Q₁,…, Q_n are the quantifiers, i.e., ∀ or ∃, and G^* is a formula without any quantifier. Then G is said to be a generalized-prenex conjunctive normal form, if G^* is a generalized-conjunctive normal form.

Definition 4.4. ^[26]

Suppose a formula G = Q₁x₁…Q_nx_nM is a generalized-prenex conjunctive normal form. The formula G^* obtained by the following steps is called a generalized-Skolem normal form of G:

1. (1)

   If Q_r is an existential quantifier and without any universal quantifier occurring ahead it in the prefix Q₁,…, Q_n (from left to right), we choose a new constant c different from other constants occurring in M, replace all x_r occurring in M by c, and then delete Q_r from the prefix Q₁,…, Q_n.

2. (2)

   If Q_r is an existential quantifier and Q_k1,…,Q_km are all the universal quantifiers occurring ahead Q_r (m ≥ 1, 1 ≤ k₁ < …< k_m < r), we choose a new m-ary function symbol fmG different from all other function symbols occurring in M, replace all x_r in M by fmG(xk1,…,xkm) and then delete Q_r from the prefix Q₁,…, Q_n.

3. (3)

   Repeating (1) and (2) until there is no existential quantifier occurring in the prefix.

Definition 4.5.

Let g₁, g₂, ..., g_n be g-literals in LF(X). A logical formula F in LF(X) is called a general g-clause if these g-literals are connected by logical connectives ˄, ∨, →, ′ and ↔, denoted by Φ(g₁, g₂,..., g_n).

Definition 4.6.

A general g-clause in LF(X) is called a constant g-clause if it contains only constants. Particularly, for a constant g-clause G, if ν_D (G) = α for any interpretation I_D = <D, µ_D, ν_D>, it follows that then this constant g-clause G is called an α-constant g-clause.

Definition 4.7.

Let Φ be a general g-clause in LF(X). A g-literal g of Φ is called a local extremely complex form, if

1. (1)

   g can’t be expanded to a more complex g-literal in Φ by adding → and ′; or

2. (2)

   If g = g₁ ↔ g₂, g₁ and g₂ are g-literals in LF(X), then g is a local extremely complex form as a whole.

Remark 4.1.

In the following, all the g-literals discussed are local extremely complex forms.

Here, the g-clause is extended to the general g-clause, i.e., the general g-clause may not be the disjunction of the g-literals; it seems that it’s too complex to explore the α-unsatisfiability of the logical formula in LF(X). Fortunately, note that every variable in the general g-Skolem normal form is universally quantified, and many properties of formulas in LF(X) do not rely on the structure of the g-clauses, many conclusions in the g-Skolem normal form still hold for general form as far as α-unsatisfiability is concerned. We only state main results as follows.

Theorem 4.1.

Let G and G^* be two logical formulas in LF(X), and G^* a general g-Skolem normal form of G, α ∈ L. Then G is α-false if and only if G^* is α-false.

Proof.

It is obvious from Theorem 2.1 in [26].

Theorem 4.2.

Suppose G^* is a general g-Skolem normal form of a formula G in LF(X). If an interpretation I_D = <D, µ_D, ν_D> α-satisfies G^*, then the H-interpretation I_H = <H, µ_H, ν_H> of G^* corresponding to I_D also α-satisfies G^*.

Proof.

It is obvious from Theorem 3.1 in [26].

Theorem 4.3.

Suppose G^* is a general g-Skolem normal form of a formula G in LF(X). Then G^* is α-false if and only if ν_H(G^*) ≱ α holds for all H-interpretations I_H = <H, µ_H, ν_H > of G^*.

Proof.

It is obvious from Theorem 3.2 in [26].

Theorem 4.4.

Suppose G^* is a general g-Skolem normal form of a formula G in LF(X), |L|<+ ∝. Then G^* is α-false if and only if there exists K∈Ν such that ν_H(G^*)≱ α holds for every adjoint ν_H of every element in L^K.

Proof.

It is obvious from Theorem 3.3 in [26].

Theorem 4.5.

Suppose G^* is a general g-Skolem normal form of a formula G in LF(X), |L|<+∝. Then G^* is α-false if and only if there exists a finite ground instance set G^*0 of G^* such that G_c^*0 is α-false, where G_c^*0 is the conjunction of all ground instances of G^*0.

Proof.

It is obvious from Theorem 3.4 in [26].

From Theorem 4.5, in order to judge the α-unsatisfiability of a formula in LF(X), when |L|<+∝, we only need to find a finite and ground instance set of this formula, and validate its α-unsatisfiability. Hence it is relatively achievable.

Definition 4.8.

Let Φ be a general g-clause in LF(X). If there exists a most general unifier σ of g-literals g₁, g₂, ..., g_m in Φ, then Φ^σ is called a factor of Φ.

Definition 4.9

(A general form of non-clausal multi- ary α-generalized resolution). Let Φ₁, Φ₂, …, Φ_n be general g-clauses in LF(X), Φ₁^σ1 be a factor of Φ₁ for g-literals g₁₁, g₁₂, … g_1r1, Φ₂^σ2 be a factor of Φ₂ for g-literals g₂₁, g₂₂, …, g_2r2, … and Φ₂^σn be a factor of Φ_n for g-literals g_n1, g_n2, … g_nrn, α∈ L. If ∧i=1ngi1σi≤α (i.e., α false), then G=∨i=1nΦiσi(gi1σi=α) is called a non-clausal n-ary α-generalized resolvent of Φ₁, Φ₂, …, Φ_n, denoted by G = R_f(N-n-α)-g (Φ₁, Φ₂, …, Φ_n), here “f” means “first-order logic”.

Definition 4.10.

Suppose S is a general g-clause set in LF(X), α ∈ L, the sequence D₁, D₂, ..., D_m is called a non-clausal multi-ary α-generalized resolution deduction from S to general g-clause D_m, if

1. (1)

   D_i ∈ S (i = 1, 2, ..., m); or

2. (2)

   There exist r_1, r₂,.…, r_ki < i, such that R_f(N-ki-α)-g (Dr_1, Dr₂, … Dr_ki = Di.

Theorem 4.6

(Lifting Lemma). If Φ⁰₁,Φ⁰₂,...,Φ⁰_n are instances of general g-clauses Φ₁, Φ₂,…, Φ_n in LF(X), respectively, P⁰ is a non-clausal multi-ary α-generalized resolvent of Φ⁰₁,Φ⁰₂,...,Φ⁰_n, then there exists a non-clausal multi-ary α-generalized resolvent P of Φ₁, Φ₂,…, Φ_n such that P⁰ is an instance of P.

Theorem 4.7.

Let Φ₁, Φ₂,…, Φ_n be general g-clauses in LF(X), Φ1σ1 be a factor of Φ₁ for g-literals g₁₁, g₁₂, …, g_1r1, Φ2σ2 be a factor of Φ₂ for g-literals g₂₁, g₂₂, … g_2r2, …, and Φnσn be a factor of Φ_n for g-literals g_n1, g_n2, …, g_nrn, α ∈L. If ∧i=1ngi1σi≤α (i.e., α false), then

Proof.

Similar to the proof of Theorem 3.1, for most general unifiers σ_i (i = 1, 2, …, n), if ∧i=1ngi1σi≤α , then ∧i=1nΦiσi≤∨i=1nΦiσi(gσii1=α) . Hence, it follows from ∧i=1nΦi≤∧i=1nΦiσi that ∧i=1nΦi≤∨i=1nΦiσi(gi1σi=α) .

Theorem 4.8 (Soundness).

Let S be a general g-clause set in LF(X), α ∈L. The sequence Φ₁, Φ₂, ..., Φ_m be a non-clausal multi-ary α-generalized resolution deduction from S to general g-clause Φ_m. If Φ_m = α-∀, then S ≤ α, i.e., S is α false.

Proof.

According to Theorem 4.7, similar to the proof of Theorem 3.2, we can easily get the conclusion.

Theorem 4.9 (Completeness).

Suppose S is the set of general g-clauses Φ₁, Φ₂, …, Φ_n in LF(X), |L|<+∝. If S ≤ α (i.e., S is α false), then there exists a non-clausal multi-ary α-generalized resolution deduction from S to α-□.

Proof.

By Theorem 4.5 and S ≤ α, there exists a finite ground instances set S₀ of S such that S₀ ≤ α. By Theorem 3.3, there exists a ground non-clausal multi-ary α-generalized resolution deduction from S₀ to α-□. By Lifting Lemma (Theorem 4.6), there exists a non-clausal multi-ary α-generalized resolution deduction from S to α-□.

Example 4.1.

Let Λ₉ = (L₉, ∨, ˄, ′, →, a₁, a₉) be a Łukasiewicz implication algebra, b, c, d constants, x, y, w, r, s, t variables in L₉F(X), S = {(P(s) ↔ Z₁(y)), (P(s) ↔ Z₁(y))′ ∨ (T(t) → W(w)), ((T(t) → W(w))→ a₂) ∨ (Z₂(s) → R(r)), (Q(y) → Z₁(b)) ∨ (R(r) → Z₁(c))′, R(r) → Z₁(d), (a₃ → Q(y))′}. If we take the resolution level α = a₆, then S ≤ α. By the completeness of non-clausal multi-ary a₆-generalized resolution (Theorem 4.9), there exists a non-clausal multi-ary a₆-generalized resolution refutation from S.

In fact, we take a ground substitution σ ={a / x, b / t, c / w, a / s, c / y, b / r} of S, then S^σ = {(P(a) ↔ Z₁(c)), (P(a) ↔ Z₁(c))′ ∨ (T(b) → W(c)), ((T(b) → W(c))→ a₂) ∨ (Z₂(a) → R(b)), (Q(c) → Z₁(b)) ∨ (R(b) → Z₁(c))′, R(b) → Z₁(d), (a₃ → Q(c))′}, and S^σ ≤ a₆, then there exists a non-clausal multi-ary α-generalized resolution refutation ω⁰ from S^σ in L₉P(X) as follows:

1. (1)

   P(a) ↔ Z₁(c)

2. (2)

   (P(a) ↔ Z₁(c))′ ∨ (T(b) → W(c))

3. (3)

   ((T(b) → W(c))→ a₂) ∨ (Z₂(a) → R(b))

4. (4)

   (Q(c) → Z₁(b)) ∨ (R(b) → Z₁(c))′

5. (5)

   R(b) → Z₁(d)

6. (6)

   (a₃ → Q(c))′

   -------------------------------

7. (7)

   a₆∨(P(a)↔ Z₁(c))′ ∨ (Z₂(a)→R(b)) by (2), (3)

8. (8)

   a₆ ∨ (R(b) → Z₁(c))′   by (4), (6)

   -------------------------------

9. (9)

   a₆ ∨ (Z₂(a) → R(b))   by (1), (7)

   -------------------------------

10. (10)

    a₆-□ by (5), (8), (9)

By Lifting Lemma of non-clausal multi-ary α -generalized resolution, there exists a non-clausal multi-ary α -generalized resolution refutation ω from S in L₉F(X), that is, we resume the variable symbols in S which are substituted by σ in S^σ. Therefore, the non-clausal multi-ary α-generalized resolution refutation of S is:

• (P(s) ↔ Z₁(y)),

• (P(s) ↔ Z₁(y))′ ∨ (T(b) → W(c)),

• ((T(b) → W(c))→ a₂) ∨ (Z₂(a) → R(b)),

• (Q(c) → Z₁(b)) ∨ (R(b) → Z₁(c))′,

• R(b) → Z₁(d),

• (a₃ → Q(y))′,

• a₆ ∨ (P(x) → (P(x) → Z₁(c))) ∨ (Z₂(s) → R(r)),

• a₆ ∨ (R(r) → Z₁(d))′,

• a₆ ∨ (Z₂(s) → R(r)),

• a₆-□.

Furthermore, if we judge the α-unsatisfiability of S by α-resolution principle, we firstly transform S to its generalized conjunctive normal form S₁ = {P(s) → Z₁(y), Z₁(y) → P(s), (P(s) → Z₁(y))′ ∨ (Z₁(y) → P(s))′ ∨ (T(t) → W(w)), ((T(t) → W(w))→ a₂) ∨ (Z₂(s) → R(r)), (Q(y) → Z₁(b)) ∨ (R(r) → Z₁(c))′, R(r) → Z₁(d), (a₃ → Q(y))′}.

Then we take a ground substitution σ ={a / x, b / t, c / w, a / s, c / y, b / r} of S₁, then S₁^σ = {P(a) → Z₁(c), Z₁(c) → P(a), (P(a) → Z₁(c))′ ∨ (Z₁(c) → P(a))′ ∨ (T(b) → W(c)), ((T(b) → W(c))→ a₂) ∨ (Z₂(a) → R(b)), (Q(c) → Z₁(b)) ∨ (R(b) → Z₁(c))′, R(b) → Z₁(d), (a₃ → Q(c))′}, and S₁^σ ≤ a₆. We cannot get a binary α -resolution refutation of S₁^σ, but can get a relatively complex multi-ary α -resolution refutation ^[24] of S₁^σ, i.e., there exists a multi-ary α -resolution refutation ω⁰ from S₁^σ in L₉P(X) as follows:

1. (1)

   P(a) → Z₁(c)

2. (2)

   Z₁(c) → P(a)

3. (3)

   (P(a)→Z₁(c))′∨ (Z₁(c)→P(a))′∨ (T(b)→ W(c))

4. (4)

   ((T(b) → W(c))→ a₂) ∨ (Z₂(a) → R(b))

5. (5)

   (Q(c) → Z₁(b)) ∨ (R(b) → Z₁(c))′

6. (6)

   R(b) → Z₁(d)

7. (7)

   (a₃ → Q(c))′

   -------------------------------

8. (8)

   a₆ ∨ (Z₁(c)→P(a))′ ∨ (T(b)→W(c))  by (1), (3)

   -------------------------------

9. (9)

   a₆ ∨ (T(b) → W(c))    by (2), (8)

   -------------------------------

10. (10)

    a₆ ∨ (Z₂(a) → R(b))    by (4), (9)

    -------------------------------

11. (11)

    a₆ ∨ (R(b) → Z₁(c))′    by (5), (10)

    -------------------------------

12. (12)

    a₆-□     by (6), (7), (11)

Similarly, by Lifting Lemma of multi-ary α -resolution, there exists a multi-ary α -resolution refutation ω from S₁ in L₉F(X), that is, we resume the variable symbols in S₁ which are substituted by σ in S₁^σ. Therefore, the multi-ary α-resolution refutation ω of S₁ is:

• P(s) → Z₁(y),

• Z₁(y) → P(s),

• (P(s) → Z₁(y))′ ∨ (Z₁(y) → P(s))′ ∨ (T(t) → W(w)),

• ((T(t) → W(w))→ a₂) ∨ (Z₂(s) → R(r)),

• (Q(y) → Z₁(b)) ∨ (R(r) → Z₁(c))′,

• R(r) → Z₁(d),

• (a₃ → Q(y))′,

• a₆ ∨ (Z₁(y) → P(s))′ ∨ (T(t) → W(w)),

• a₆ ∨ (T(t) → W(w)),

• a₆ ∨ (Z₂(s) → R(r)),

• a₆ ∨ (R(r) → Z₁(c))′,

• a₆-□.

Example 4.2.

Let (L₆, ∨, ˄, ′, →, O, I) be an LIA defined as Example 2.4, a, c, d ∈ L₆, x, y, z, t, w, u variable symbols in L₆F(X), S = {P(x), (P(x)→ d) ∨(Z₁(w) ↔ Q(y)), (Z₁(w) ↔ Q(y))′ ∨ (T(z) → d), Z(t) → T(z), (Z(t) → Z₁(u))′}. If we take the resolution level α = d, then S ≤ d. By the completeness of non-clausal multi-ray d-generalized resolution (Theorem 4.9), there exists a non-clausal multi-ray d-generalized resolution refutation from S.

In fact, we take a ground substitution σ ={a₁ / x, a₂ / y, a₃ / z, a₄ / t, a₅ / u, a₁ / w} of S, where a₁, a₂, a₃, a₄, and a₅ are constant symbols in L₆F(X), then S^σ = {P(a₁), (P(a₁)→ d) ∨ (Z₁(a₁) ↔ Q(a₂)), (Z₁(a₁) ↔ Q(a₂))′ ∨ (T(a₃) → d), Z(a₄) → T(a₃), (Z(a₄) → Z₁(a₅))′}, and S^σ ≤ d, then there exists a non-clausal multi-ray α -generalized resolution refutation ω⁰ from S^σ in L₆P(X) as follows:

1. (1)

   P(a₁)

2. (2)

   (P(a₁)→ d) ∨ (Z₁(a₁) ↔ Q(a₂))

3. (3)

   (Z₁(a₁) ↔ Q(a₂))′ ∨ (T(a₃) → d)

4. (4)

   Z(a₄) → T(a₃)

5. (5)

   (Z(a₄) → Z₁(a₅))′

   -------------------------------

6. (6)

   d ∨ (Z₁(a₁) ↔ Q(a₂))   by (1), (2)

   -------------------------------

7. (7)

   d ∨ (T(a₃) → d)    by (3), (6)

   -------------------------------

8. (8)

   d-□ by (4), (5), (7)

By Lifting Lemma of non-clausal multi-ray α-generalized resolution, there exists a non-clausal multi-ray α-generalized resolution refutation ω from S in L₆F(X) similar to Example 4.1. Therefore, the non-clausal multi-ray α-generalized resolution refutation ω of S is:

• P(a₁),

• (P(a₁)→ d) ∨ (Z₁(w) ↔ Q(y)),

• (Z₁(w) ↔ Q(y))′ ∨ (T(a₃) → d),

• Z(a₄) → T(a₃),

• (Z(a₄) → Z₁(a₅))′,

• d ∨ Q(y),

• d ∨ (T(z) → d),

• d-□.

Furthermore, if we judge the α-unsatisfiability of S by α-resolution principle, we firstly transform S to its generalized conjunctive normal form S₁ = {P(x), (P(x)→d) ∨(Z₁(w) → Q(y)), (P(x)→ d) ∨(Q(y) → Z₁(w)), (Z₁(w) → Q(y))′ ∨ (Q(y) → Z₁(w))′ ∨ (T(z) → d), Z(t) → T(z), (Z(t) → Z₁(u))′}.

Then we take a ground substitution σ ={a₁ / x, a₂ / y, a₃ / z, a₄ / t, a₅ / u, a₁ / w} of S, then S₁^σ = {P(a₁), (P(a₁)→ d)∨(Z₁(a₁) → Q(a₂)), (P(a₁)→ d) ∨ (Q(a₂) → Z₁(a₁)), (Z₁(a₁) → Q(a₂))′ ∨ (Q(a₂) → Z₁(a₁))′ ∨ (T(a₃) → d), Z(a₄) → T(a₃), (Z(a₄) → Z₁(a₅))′}, and S₁^σ ∨≤ d, then we cannot get a binary α-resolution refutation of S₁^σ, but can get a relatively complex multi-ray α-resolution refutation of S₁^{σ [24]}, i.e., there exists a multi-ray α-resolution refutation ω⁰ from S₁^σ in L₆F(X) as follows:

1. (1)

   P(a₁)

2. (2)

   (P(a₁)→ d)∨(Z₁(a₁) → Q(a₂))

3. (3)

   (P(a₁)→ d) ∨ (Q(a₂) → Z₁(a₁))

4. (4)

   (Z₁(a₁)→Q(a₂))′∨(Q(a₂)→Z₁(a₁))′∨(T(a₃)→d)

5. (5)

   Z(a₄) → T(a₃)

6. (6)

   (Z(a₄) → Z₁(a₅))′

   -------------------------------

7. (7)

   d ∨ (Z₁(a₁) → Q(a₂))   by (1), (2)

8. (8)

   d ∨ (Q(a₂) → Z₁(a₁))   by (1), (3)

   -------------------------------

9. (9)

   d∨(Q(a₂)→ Z₁(a₁))′ ∨ (T(a₃)→d)  by (4), (7)

   -------------------------------

10. (10)

    d ∨ (T(a₃) → d)    by (8), (9)

    -------------------------------

11. (11)

    d-□     by (5), (6), (10)

Similarly, by Lifting Lemma of multi-ray α-resolution, there exists a multi-ray α-resolution refutation ω from S₁ in L₆F(X), that is, we resume the variable symbols in S₁ which are substituted by σ in S₁^σ. Therefore, the multi-ray α-resolution refutation ω of S₁ is:

• P(x),

• (P(x)→ d) ∨(Z₁(w) → Q(y)),

• (P(x)→ d) ∨(Q(y) → Z₁(w)),

• (Z₁(w) → Q(y))′ ∨ (Q(y) → Z₁(w))′ ∨ (T(z) → d),

• Z(t) → T(z),

• (Z(t) → Z₁(u))′

• d ∨ (Z₁(w) → Q(y)),

• d ∨ (Q(y) → Z₁(w)),

• d ∨ (Q(y) → Z₁(w))′ ∨ (T(z) → d),

• d ∨ (T(z) → d),

• d-□.

Theorem 4.8 and Theorem 4.9 show that the non-clausal multi-ray α-generalized resolution deduction in LF(X) is sound and complete, along with Examples 4.1 and 4.2 to illustrate its advantages in terms of reasoning capability and efficiency. Similarly in LP(X), Examples 4.1 and 4.2 show that for an α -unsatisfiable set of general g-clause in LF(X), if we convert it into respectively generalized conjunctive normal form, and judge it by α-resolution principle, then it may not lead to a binary α-resolution refutation partially because its restriction of the number of α -resloved literals is 2. Although sometimes it may lead to a multi-ray α-resolution refutation, but it is more complex than the non-clausal multi-ray α-resolution refutation.

Consequently, the proposed work is a great extension of the results in [24–26] in terms of soundness and completeness, applicability, reasoning capability and reasoning efficiency.

Remark 4.2.

In fact, it follows from Theorem 4.5 that the determination of α-generalized resolution in LF(X) can be equivalently transformed into that of α -generalized resolution in LP(X) to some extents, which reduces the difficulty of α -generalized resolution in LF(X) to some extents. Hence, the determination of α -generalized resolution in LP(X) would be the next key step for developing efficient α-resolution reasoning algorithm for LP(X) as well as LF(X). However, similar to the one indicated in [24], the practical implementations of a resolution deduction algorithm are much more complex, especially in the case of first-order logic. It can be tracked back to 1931 when Godel proposed the famous undecidability theory, that is, it is impossible to construct a single algorithm that can always lead to a correct true-or-false answer for all logical formulae in a specified deductive system.

The focus of this paper is on the resolution principle and the theoretical soundness and completeness of this resolution-based automated deduction, not on the concrete algorithms or search strategies for implementation. For resolution-based automated reasoning in lattice-valued logic based on LIE, 1) it is more complex than that in classical logic from the logical point of view; 2) it will be not that straightforward either in determining or search which group of generalized literals could be α -resoluble, that is, resoluble at a truth-value level α, or determining at least how many generalized literals can be chosen in the α -resolution group once given a truth-value level α; 3) although the resolution process can borrow the similar ideas from classical logic, it becomes more complex due to the more complex generalized literals involved in the resolution and also the fact that it allows the choice of various truth-value level resolution (different from the only case of α=O in classical logic).

Consequently, it is much harder or more computationally complex to achieve the α-resolution-based automated reasoning algorithm in lattice-valued logic based on LIE than to achieve it in the classical logic. This kind of concrete algorithms or search strategies for implementation will be still one of challenge problems in α-resolution-based automated reasoning in lattice-valued logic based on LIE, will need more efforts to investigate in the future, this topic, however, is beyond the scope of the present work.