proof for relational predicate logic











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I have been working on this problem for over an hour and I think I have simply missed something. I need some help. The rules I am allowed to use are the Basic Inference rules (MP, MT, HS, Simp, Conj, DS, Add, CD), the Replacement Rules (DN, Comm, Assoc, Dup, DeM, BE, Contrap, CE, Exp, Dist.), CP, IP, and EI, UI, EG, UG.



The problem is:




  1. ¬(∃x)(Axa ∧ ~Bxb)

  2. ¬(∃x)(Cxc ∧ Cbx)

  3. (∀x)(Bex → Cxf)


/∴ ¬(Aea ∧ Cfc)



Any help would be appreciated. Thanks.



Edit: Fixed the format of the question. The system is quantificational predicate logic. I've never called it anything else.










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  • 1




    This formula is unreadable. Please reformat it with ∀, ∃ for quantifiers, ∨, ∧, →, ¬ for connectives (you can copy symbols from here), and predicates as P(x,y,z). What > and // are I can not even guess. "Basic Inference rules" and "Replacement Rules" are specific to your book and not standard terminology, so best provide a reference and what type of system it is using (natural deduction, sequent calculus, something else?).
    – Conifold
    3 hours ago








  • 1




    I formatted the premises and conclusion to use Conifold's symbols. You may roll this back or continue editing if I got it wrong.
    – Frank Hubeny
    2 hours ago















up vote
3
down vote

favorite












I have been working on this problem for over an hour and I think I have simply missed something. I need some help. The rules I am allowed to use are the Basic Inference rules (MP, MT, HS, Simp, Conj, DS, Add, CD), the Replacement Rules (DN, Comm, Assoc, Dup, DeM, BE, Contrap, CE, Exp, Dist.), CP, IP, and EI, UI, EG, UG.



The problem is:




  1. ¬(∃x)(Axa ∧ ~Bxb)

  2. ¬(∃x)(Cxc ∧ Cbx)

  3. (∀x)(Bex → Cxf)


/∴ ¬(Aea ∧ Cfc)



Any help would be appreciated. Thanks.



Edit: Fixed the format of the question. The system is quantificational predicate logic. I've never called it anything else.










share|improve this question









New contributor




fantasticorangina is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
















  • 1




    This formula is unreadable. Please reformat it with ∀, ∃ for quantifiers, ∨, ∧, →, ¬ for connectives (you can copy symbols from here), and predicates as P(x,y,z). What > and // are I can not even guess. "Basic Inference rules" and "Replacement Rules" are specific to your book and not standard terminology, so best provide a reference and what type of system it is using (natural deduction, sequent calculus, something else?).
    – Conifold
    3 hours ago








  • 1




    I formatted the premises and conclusion to use Conifold's symbols. You may roll this back or continue editing if I got it wrong.
    – Frank Hubeny
    2 hours ago













up vote
3
down vote

favorite









up vote
3
down vote

favorite











I have been working on this problem for over an hour and I think I have simply missed something. I need some help. The rules I am allowed to use are the Basic Inference rules (MP, MT, HS, Simp, Conj, DS, Add, CD), the Replacement Rules (DN, Comm, Assoc, Dup, DeM, BE, Contrap, CE, Exp, Dist.), CP, IP, and EI, UI, EG, UG.



The problem is:




  1. ¬(∃x)(Axa ∧ ~Bxb)

  2. ¬(∃x)(Cxc ∧ Cbx)

  3. (∀x)(Bex → Cxf)


/∴ ¬(Aea ∧ Cfc)



Any help would be appreciated. Thanks.



Edit: Fixed the format of the question. The system is quantificational predicate logic. I've never called it anything else.










share|improve this question









New contributor




fantasticorangina is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.











I have been working on this problem for over an hour and I think I have simply missed something. I need some help. The rules I am allowed to use are the Basic Inference rules (MP, MT, HS, Simp, Conj, DS, Add, CD), the Replacement Rules (DN, Comm, Assoc, Dup, DeM, BE, Contrap, CE, Exp, Dist.), CP, IP, and EI, UI, EG, UG.



The problem is:




  1. ¬(∃x)(Axa ∧ ~Bxb)

  2. ¬(∃x)(Cxc ∧ Cbx)

  3. (∀x)(Bex → Cxf)


/∴ ¬(Aea ∧ Cfc)



Any help would be appreciated. Thanks.



Edit: Fixed the format of the question. The system is quantificational predicate logic. I've never called it anything else.







logic symbolic-logic






share|improve this question









New contributor




fantasticorangina is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.











share|improve this question









New contributor




fantasticorangina is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.









share|improve this question




share|improve this question








edited 2 hours ago









Frank Hubeny

6,18141244




6,18141244






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asked 3 hours ago









fantasticorangina

162




162




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  • 1




    This formula is unreadable. Please reformat it with ∀, ∃ for quantifiers, ∨, ∧, →, ¬ for connectives (you can copy symbols from here), and predicates as P(x,y,z). What > and // are I can not even guess. "Basic Inference rules" and "Replacement Rules" are specific to your book and not standard terminology, so best provide a reference and what type of system it is using (natural deduction, sequent calculus, something else?).
    – Conifold
    3 hours ago








  • 1




    I formatted the premises and conclusion to use Conifold's symbols. You may roll this back or continue editing if I got it wrong.
    – Frank Hubeny
    2 hours ago














  • 1




    This formula is unreadable. Please reformat it with ∀, ∃ for quantifiers, ∨, ∧, →, ¬ for connectives (you can copy symbols from here), and predicates as P(x,y,z). What > and // are I can not even guess. "Basic Inference rules" and "Replacement Rules" are specific to your book and not standard terminology, so best provide a reference and what type of system it is using (natural deduction, sequent calculus, something else?).
    – Conifold
    3 hours ago








  • 1




    I formatted the premises and conclusion to use Conifold's symbols. You may roll this back or continue editing if I got it wrong.
    – Frank Hubeny
    2 hours ago








1




1




This formula is unreadable. Please reformat it with ∀, ∃ for quantifiers, ∨, ∧, →, ¬ for connectives (you can copy symbols from here), and predicates as P(x,y,z). What > and // are I can not even guess. "Basic Inference rules" and "Replacement Rules" are specific to your book and not standard terminology, so best provide a reference and what type of system it is using (natural deduction, sequent calculus, something else?).
– Conifold
3 hours ago






This formula is unreadable. Please reformat it with ∀, ∃ for quantifiers, ∨, ∧, →, ¬ for connectives (you can copy symbols from here), and predicates as P(x,y,z). What > and // are I can not even guess. "Basic Inference rules" and "Replacement Rules" are specific to your book and not standard terminology, so best provide a reference and what type of system it is using (natural deduction, sequent calculus, something else?).
– Conifold
3 hours ago






1




1




I formatted the premises and conclusion to use Conifold's symbols. You may roll this back or continue editing if I got it wrong.
– Frank Hubeny
2 hours ago




I formatted the premises and conclusion to use Conifold's symbols. You may roll this back or continue editing if I got it wrong.
– Frank Hubeny
2 hours ago










2 Answers
2






active

oldest

votes

















up vote
1
down vote













It is useful to have a proof checker to aid learning how to use natural deduction. I have linked to one below in the references.



Using that proof checker and the rules described in forallx I was able to prove the result in 22 lines which included 3 lines for the premises and 1 line for the goal.



Although I don't see it listed I assume you have the change of quantifier replacement rule. If not a derivation is in forallx on pages 260-1. Use that to change the first two premises from "~(∃x)" to "(∀x)~".



Next eliminate the universal quantifier by assigning a different name to the variable "x" in each premise. You should chose these names wisely. Look at the goal to try to pick names that will help you reach the goal.



Then use De Morgan rules to transform the lines with a negation in front of the conjunction to a disjunction of negations.



After that preparatory work, I derived something like the following line: "¬Aea ∨ ¬¬Beb". I used disjunction elimination by considering both cases. I wanted to reach the following: "¬Aea ∨ ¬Cfc". Now that is not quite the desired result but with a use of the De Morgan rules I could convert that into the final goal: "¬(Aea ∧ Cfc)".





References



Kevin Klement's JavaScript/PHP Fitch-style natural deduction proof editor and checker http://proofs.openlogicproject.org/



P. D. Magnus, Tim Button with additions by J. Robert Loftis remixed and revised by Aaron Thomas-Bolduc, Richard Zach, forallx Calgary Remix: An Introduction to Formal Logic, Winter 2018. http://forallx.openlogicproject.org/






share|improve this answer




























    up vote
    1
    down vote













    Use an Indirect Proof.



    Begin by assuming (Aea ∧ Cfc), use the first premise to derive Beb, the third to derive Cbf, and the second to derive a contradiction.



    Some of your subproofs will likewise be Indirect Proofs; using existential generalisation to derive their contradictions.



    Assuming, that the thing you call IP operates as expected (derive a contradiction from an assumption, thereby deducing that the negation of the assumption holds).






    share|improve this answer























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      2 Answers
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      active

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      2 Answers
      2






      active

      oldest

      votes









      active

      oldest

      votes






      active

      oldest

      votes








      up vote
      1
      down vote













      It is useful to have a proof checker to aid learning how to use natural deduction. I have linked to one below in the references.



      Using that proof checker and the rules described in forallx I was able to prove the result in 22 lines which included 3 lines for the premises and 1 line for the goal.



      Although I don't see it listed I assume you have the change of quantifier replacement rule. If not a derivation is in forallx on pages 260-1. Use that to change the first two premises from "~(∃x)" to "(∀x)~".



      Next eliminate the universal quantifier by assigning a different name to the variable "x" in each premise. You should chose these names wisely. Look at the goal to try to pick names that will help you reach the goal.



      Then use De Morgan rules to transform the lines with a negation in front of the conjunction to a disjunction of negations.



      After that preparatory work, I derived something like the following line: "¬Aea ∨ ¬¬Beb". I used disjunction elimination by considering both cases. I wanted to reach the following: "¬Aea ∨ ¬Cfc". Now that is not quite the desired result but with a use of the De Morgan rules I could convert that into the final goal: "¬(Aea ∧ Cfc)".





      References



      Kevin Klement's JavaScript/PHP Fitch-style natural deduction proof editor and checker http://proofs.openlogicproject.org/



      P. D. Magnus, Tim Button with additions by J. Robert Loftis remixed and revised by Aaron Thomas-Bolduc, Richard Zach, forallx Calgary Remix: An Introduction to Formal Logic, Winter 2018. http://forallx.openlogicproject.org/






      share|improve this answer

























        up vote
        1
        down vote













        It is useful to have a proof checker to aid learning how to use natural deduction. I have linked to one below in the references.



        Using that proof checker and the rules described in forallx I was able to prove the result in 22 lines which included 3 lines for the premises and 1 line for the goal.



        Although I don't see it listed I assume you have the change of quantifier replacement rule. If not a derivation is in forallx on pages 260-1. Use that to change the first two premises from "~(∃x)" to "(∀x)~".



        Next eliminate the universal quantifier by assigning a different name to the variable "x" in each premise. You should chose these names wisely. Look at the goal to try to pick names that will help you reach the goal.



        Then use De Morgan rules to transform the lines with a negation in front of the conjunction to a disjunction of negations.



        After that preparatory work, I derived something like the following line: "¬Aea ∨ ¬¬Beb". I used disjunction elimination by considering both cases. I wanted to reach the following: "¬Aea ∨ ¬Cfc". Now that is not quite the desired result but with a use of the De Morgan rules I could convert that into the final goal: "¬(Aea ∧ Cfc)".





        References



        Kevin Klement's JavaScript/PHP Fitch-style natural deduction proof editor and checker http://proofs.openlogicproject.org/



        P. D. Magnus, Tim Button with additions by J. Robert Loftis remixed and revised by Aaron Thomas-Bolduc, Richard Zach, forallx Calgary Remix: An Introduction to Formal Logic, Winter 2018. http://forallx.openlogicproject.org/






        share|improve this answer























          up vote
          1
          down vote










          up vote
          1
          down vote









          It is useful to have a proof checker to aid learning how to use natural deduction. I have linked to one below in the references.



          Using that proof checker and the rules described in forallx I was able to prove the result in 22 lines which included 3 lines for the premises and 1 line for the goal.



          Although I don't see it listed I assume you have the change of quantifier replacement rule. If not a derivation is in forallx on pages 260-1. Use that to change the first two premises from "~(∃x)" to "(∀x)~".



          Next eliminate the universal quantifier by assigning a different name to the variable "x" in each premise. You should chose these names wisely. Look at the goal to try to pick names that will help you reach the goal.



          Then use De Morgan rules to transform the lines with a negation in front of the conjunction to a disjunction of negations.



          After that preparatory work, I derived something like the following line: "¬Aea ∨ ¬¬Beb". I used disjunction elimination by considering both cases. I wanted to reach the following: "¬Aea ∨ ¬Cfc". Now that is not quite the desired result but with a use of the De Morgan rules I could convert that into the final goal: "¬(Aea ∧ Cfc)".





          References



          Kevin Klement's JavaScript/PHP Fitch-style natural deduction proof editor and checker http://proofs.openlogicproject.org/



          P. D. Magnus, Tim Button with additions by J. Robert Loftis remixed and revised by Aaron Thomas-Bolduc, Richard Zach, forallx Calgary Remix: An Introduction to Formal Logic, Winter 2018. http://forallx.openlogicproject.org/






          share|improve this answer












          It is useful to have a proof checker to aid learning how to use natural deduction. I have linked to one below in the references.



          Using that proof checker and the rules described in forallx I was able to prove the result in 22 lines which included 3 lines for the premises and 1 line for the goal.



          Although I don't see it listed I assume you have the change of quantifier replacement rule. If not a derivation is in forallx on pages 260-1. Use that to change the first two premises from "~(∃x)" to "(∀x)~".



          Next eliminate the universal quantifier by assigning a different name to the variable "x" in each premise. You should chose these names wisely. Look at the goal to try to pick names that will help you reach the goal.



          Then use De Morgan rules to transform the lines with a negation in front of the conjunction to a disjunction of negations.



          After that preparatory work, I derived something like the following line: "¬Aea ∨ ¬¬Beb". I used disjunction elimination by considering both cases. I wanted to reach the following: "¬Aea ∨ ¬Cfc". Now that is not quite the desired result but with a use of the De Morgan rules I could convert that into the final goal: "¬(Aea ∧ Cfc)".





          References



          Kevin Klement's JavaScript/PHP Fitch-style natural deduction proof editor and checker http://proofs.openlogicproject.org/



          P. D. Magnus, Tim Button with additions by J. Robert Loftis remixed and revised by Aaron Thomas-Bolduc, Richard Zach, forallx Calgary Remix: An Introduction to Formal Logic, Winter 2018. http://forallx.openlogicproject.org/







          share|improve this answer












          share|improve this answer



          share|improve this answer










          answered 2 hours ago









          Frank Hubeny

          6,18141244




          6,18141244






















              up vote
              1
              down vote













              Use an Indirect Proof.



              Begin by assuming (Aea ∧ Cfc), use the first premise to derive Beb, the third to derive Cbf, and the second to derive a contradiction.



              Some of your subproofs will likewise be Indirect Proofs; using existential generalisation to derive their contradictions.



              Assuming, that the thing you call IP operates as expected (derive a contradiction from an assumption, thereby deducing that the negation of the assumption holds).






              share|improve this answer



























                up vote
                1
                down vote













                Use an Indirect Proof.



                Begin by assuming (Aea ∧ Cfc), use the first premise to derive Beb, the third to derive Cbf, and the second to derive a contradiction.



                Some of your subproofs will likewise be Indirect Proofs; using existential generalisation to derive their contradictions.



                Assuming, that the thing you call IP operates as expected (derive a contradiction from an assumption, thereby deducing that the negation of the assumption holds).






                share|improve this answer

























                  up vote
                  1
                  down vote










                  up vote
                  1
                  down vote









                  Use an Indirect Proof.



                  Begin by assuming (Aea ∧ Cfc), use the first premise to derive Beb, the third to derive Cbf, and the second to derive a contradiction.



                  Some of your subproofs will likewise be Indirect Proofs; using existential generalisation to derive their contradictions.



                  Assuming, that the thing you call IP operates as expected (derive a contradiction from an assumption, thereby deducing that the negation of the assumption holds).






                  share|improve this answer














                  Use an Indirect Proof.



                  Begin by assuming (Aea ∧ Cfc), use the first premise to derive Beb, the third to derive Cbf, and the second to derive a contradiction.



                  Some of your subproofs will likewise be Indirect Proofs; using existential generalisation to derive their contradictions.



                  Assuming, that the thing you call IP operates as expected (derive a contradiction from an assumption, thereby deducing that the negation of the assumption holds).







                  share|improve this answer














                  share|improve this answer



                  share|improve this answer








                  edited 1 hour ago

























                  answered 1 hour ago









                  Graham Kemp

                  83018




                  83018






















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