TSTP Solution File: MGT020-1 by Zipperpin---2.1.9999
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- Process Solution
%------------------------------------------------------------------------------
% File : Zipperpin---2.1.9999
% Problem : MGT020-1 : TPTP v8.1.2. Released v2.4.0.
% Transfm : NO INFORMATION
% Format : NO INFORMATION
% Command : python3 /export/starexec/sandbox2/solver/bin/portfolio.lams.parallel.py %s %d /export/starexec/sandbox2/tmp/tmp.gpzpAGPTDZ true
% Computer : n029.cluster.edu
% Model : x86_64 x86_64
% CPU : Intel(R) Xeon(R) CPU E5-2620 v4 2.10GHz
% Memory : 8042.1875MB
% OS : Linux 3.10.0-693.el7.x86_64
% CPULimit : 300s
% WCLimit : 300s
% DateTime : Thu Aug 31 09:19:52 EDT 2023
% Result : Unsatisfiable 0.76s 0.80s
% Output : Refutation 0.76s
% Verified :
% SZS Type : -
% Comments :
%------------------------------------------------------------------------------
%----WARNING: Could not form TPTP format derivation
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.00/0.12 % Problem : MGT020-1 : TPTP v8.1.2. Released v2.4.0.
% 0.00/0.13 % Command : python3 /export/starexec/sandbox2/solver/bin/portfolio.lams.parallel.py %s %d /export/starexec/sandbox2/tmp/tmp.gpzpAGPTDZ true
% 0.13/0.34 % Computer : n029.cluster.edu
% 0.13/0.34 % Model : x86_64 x86_64
% 0.13/0.34 % CPU : Intel(R) Xeon(R) CPU E5-2620 v4 @ 2.10GHz
% 0.13/0.34 % Memory : 8042.1875MB
% 0.13/0.34 % OS : Linux 3.10.0-693.el7.x86_64
% 0.13/0.34 % CPULimit : 300
% 0.13/0.34 % WCLimit : 300
% 0.13/0.34 % DateTime : Mon Aug 28 06:53:41 EDT 2023
% 0.13/0.35 % CPUTime :
% 0.13/0.35 % Running portfolio for 300 s
% 0.13/0.35 % File : /export/starexec/sandbox2/benchmark/theBenchmark.p
% 0.13/0.35 % Number of cores: 8
% 0.13/0.35 % Python version: Python 3.6.8
% 0.13/0.35 % Running in FO mode
% 0.20/0.66 % Total configuration time : 435
% 0.20/0.66 % Estimated wc time : 1092
% 0.20/0.66 % Estimated cpu time (7 cpus) : 156.0
% 0.20/0.71 % /export/starexec/sandbox2/solver/bin/fo/fo6_bce.sh running for 75s
% 0.20/0.73 % /export/starexec/sandbox2/solver/bin/fo/fo3_bce.sh running for 75s
% 0.20/0.73 % /export/starexec/sandbox2/solver/bin/fo/fo1_av.sh running for 75s
% 0.20/0.74 % /export/starexec/sandbox2/solver/bin/fo/fo7.sh running for 63s
% 0.20/0.75 % /export/starexec/sandbox2/solver/bin/fo/fo13.sh running for 50s
% 0.20/0.76 % /export/starexec/sandbox2/solver/bin/fo/fo5.sh running for 50s
% 0.20/0.79 % /export/starexec/sandbox2/solver/bin/fo/fo4.sh running for 50s
% 0.76/0.80 % Solved by fo/fo6_bce.sh.
% 0.76/0.80 % BCE start: 14
% 0.76/0.80 % BCE eliminated: 0
% 0.76/0.80 % PE start: 14
% 0.76/0.80 logic: eq
% 0.76/0.80 % PE eliminated: 1
% 0.76/0.80 % done 69 iterations in 0.071s
% 0.76/0.80 % SZS status Theorem for '/export/starexec/sandbox2/benchmark/theBenchmark.p'
% 0.76/0.80 % SZS output start Refutation
% 0.76/0.80 thf(difference_type, type, difference: $i > $i > $i).
% 0.76/0.80 thf(greater_type, type, greater: $i > $i > $o).
% 0.76/0.80 thf(in_environment_type, type, in_environment: $i > $i > $o).
% 0.76/0.80 thf(sk1_type, type, sk1: $i).
% 0.76/0.80 thf(environment_type, type, environment: $i > $o).
% 0.76/0.80 thf(decreases_type, type, decreases: $i > $o).
% 0.76/0.80 thf(initial_FM_EP_type, type, initial_FM_EP: $i > $i).
% 0.76/0.80 thf(start_time_type, type, start_time: $i > $i).
% 0.76/0.80 thf(subpopulations_type, type, subpopulations: $i > $i > $i > $i > $o).
% 0.76/0.80 thf(greater_or_equal_type, type, greater_or_equal: $i > $i > $o).
% 0.76/0.80 thf(sk2_type, type, sk2: $i).
% 0.76/0.80 thf(disbanding_rate_type, type, disbanding_rate: $i > $i > $i).
% 0.76/0.80 thf(first_movers_type, type, first_movers: $i).
% 0.76/0.80 thf(efficient_producers_type, type, efficient_producers: $i).
% 0.76/0.80 thf(prove_l2_35, conjecture,
% 0.76/0.80 (greater @
% 0.76/0.80 ( disbanding_rate @ first_movers @ sk2 ) @
% 0.76/0.80 ( disbanding_rate @ efficient_producers @ sk2 ))).
% 0.76/0.80 thf(zf_stmt_0, negated_conjecture,
% 0.76/0.80 (~( greater @
% 0.76/0.80 ( disbanding_rate @ first_movers @ sk2 ) @
% 0.76/0.80 ( disbanding_rate @ efficient_producers @ sk2 ) )),
% 0.76/0.80 inference('cnf.neg', [status(esa)], [prove_l2_35])).
% 0.76/0.80 thf(zip_derived_cl13, plain,
% 0.76/0.80 (~ (greater @ (disbanding_rate @ first_movers @ sk2) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ sk2))),
% 0.76/0.80 inference('cnf', [status(esa)], [zf_stmt_0])).
% 0.76/0.80 thf(prove_l2_34, conjecture,
% 0.76/0.80 (~( subpopulations @ first_movers @ efficient_producers @ sk1 @ sk2 ))).
% 0.76/0.80 thf(zf_stmt_1, negated_conjecture,
% 0.76/0.80 (subpopulations @ first_movers @ efficient_producers @ sk1 @ sk2),
% 0.76/0.80 inference('cnf.neg', [status(esa)], [prove_l2_34])).
% 0.76/0.80 thf(zip_derived_cl12, plain,
% 0.76/0.80 ( (subpopulations @ first_movers @ efficient_producers @ sk1 @ sk2)),
% 0.76/0.80 inference('cnf', [status(esa)], [zf_stmt_1])).
% 0.76/0.80 thf(mp_earliest_time_point_24, axiom,
% 0.76/0.80 (( ~( environment @ A ) ) |
% 0.76/0.80 ( ~( subpopulations @ first_movers @ efficient_producers @ A @ B ) ) |
% 0.76/0.80 ( greater_or_equal @ B @ ( initial_FM_EP @ A ) ))).
% 0.76/0.80 thf(zip_derived_cl2, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i]:
% 0.76/0.80 (~ (environment @ X0)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @ X1)
% 0.76/0.80 | (greater_or_equal @ X1 @ (initial_FM_EP @ X0)))),
% 0.76/0.80 inference('cnf', [status(esa)], [mp_earliest_time_point_24])).
% 0.76/0.80 thf(mp_greater_or_equal_30, axiom,
% 0.76/0.80 (( ~( greater_or_equal @ A @ B ) ) | ( greater @ A @ B ) |
% 0.76/0.80 ( ( A ) = ( B ) ))).
% 0.76/0.80 thf(zip_derived_cl8, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i]:
% 0.76/0.80 (~ (greater_or_equal @ X0 @ X1) | (greater @ X0 @ X1) | ((X0) = (X1)))),
% 0.76/0.80 inference('cnf', [status(esa)], [mp_greater_or_equal_30])).
% 0.76/0.80 thf(zip_derived_cl106, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i]:
% 0.76/0.80 (~ (subpopulations @ first_movers @ efficient_producers @ X0 @ X1)
% 0.76/0.80 | ~ (environment @ X0)
% 0.76/0.80 | (greater @ X1 @ (initial_FM_EP @ X0))
% 0.76/0.80 | ((X1) = (initial_FM_EP @ X0)))),
% 0.76/0.80 inference('s_sup-', [status(thm)], [zip_derived_cl2, zip_derived_cl8])).
% 0.76/0.80 thf(mp_initial_time_27, axiom,
% 0.76/0.80 (( ~( environment @ A ) ) |
% 0.76/0.80 ( greater_or_equal @ ( initial_FM_EP @ A ) @ ( start_time @ A ) ))).
% 0.76/0.80 thf(zip_derived_cl5, plain,
% 0.76/0.80 (![X0 : $i]:
% 0.76/0.80 (~ (environment @ X0)
% 0.76/0.80 | (greater_or_equal @ (initial_FM_EP @ X0) @ (start_time @ X0)))),
% 0.76/0.80 inference('cnf', [status(esa)], [mp_initial_time_27])).
% 0.76/0.80 thf(mp_times_in_order_28, axiom,
% 0.76/0.80 (( ~( environment @ A ) ) |
% 0.76/0.80 ( ~( greater_or_equal @ B @ ( start_time @ A ) ) ) |
% 0.76/0.80 ( ~( greater @ C @ B ) ) | ( ~( in_environment @ A @ C ) ) |
% 0.76/0.80 ( in_environment @ A @ B ))).
% 0.76/0.80 thf(zip_derived_cl6, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i, X2 : $i]:
% 0.76/0.80 (~ (environment @ X0)
% 0.76/0.80 | ~ (greater_or_equal @ X1 @ (start_time @ X0))
% 0.76/0.80 | ~ (greater @ X2 @ X1)
% 0.76/0.80 | ~ (in_environment @ X0 @ X2)
% 0.76/0.80 | (in_environment @ X0 @ X1))),
% 0.76/0.80 inference('cnf', [status(esa)], [mp_times_in_order_28])).
% 0.76/0.80 thf(zip_derived_cl109, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i]:
% 0.76/0.80 (~ (environment @ X0)
% 0.76/0.80 | ~ (environment @ X0)
% 0.76/0.80 | ~ (greater @ X1 @ (initial_FM_EP @ X0))
% 0.76/0.80 | ~ (in_environment @ X0 @ X1)
% 0.76/0.80 | (in_environment @ X0 @ (initial_FM_EP @ X0)))),
% 0.76/0.80 inference('s_sup-', [status(thm)], [zip_derived_cl5, zip_derived_cl6])).
% 0.76/0.80 thf(zip_derived_cl110, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i]:
% 0.76/0.80 ( (in_environment @ X0 @ (initial_FM_EP @ X0))
% 0.76/0.80 | ~ (in_environment @ X0 @ X1)
% 0.76/0.80 | ~ (greater @ X1 @ (initial_FM_EP @ X0))
% 0.76/0.80 | ~ (environment @ X0))),
% 0.76/0.80 inference('simplify', [status(thm)], [zip_derived_cl109])).
% 0.76/0.80 thf(zip_derived_cl118, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i]:
% 0.76/0.80 (((X1) = (initial_FM_EP @ X0))
% 0.76/0.80 | ~ (environment @ X0)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @ X1)
% 0.76/0.80 | (in_environment @ X0 @ (initial_FM_EP @ X0))
% 0.76/0.80 | ~ (in_environment @ X0 @ X1)
% 0.76/0.80 | ~ (environment @ X0))),
% 0.76/0.80 inference('s_sup-', [status(thm)], [zip_derived_cl106, zip_derived_cl110])).
% 0.76/0.80 thf(zip_derived_cl119, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i]:
% 0.76/0.80 (~ (in_environment @ X0 @ X1)
% 0.76/0.80 | (in_environment @ X0 @ (initial_FM_EP @ X0))
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @ X1)
% 0.76/0.80 | ~ (environment @ X0)
% 0.76/0.80 | ((X1) = (initial_FM_EP @ X0)))),
% 0.76/0.80 inference('simplify', [status(thm)], [zip_derived_cl118])).
% 0.76/0.80 thf(mp_time_point_occurs_26, axiom,
% 0.76/0.80 (( ~( environment @ A ) ) |
% 0.76/0.80 ( ~( subpopulations @ first_movers @ efficient_producers @ A @ B ) ) |
% 0.76/0.80 ( in_environment @ A @ B ))).
% 0.76/0.80 thf(zip_derived_cl4, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i]:
% 0.76/0.80 (~ (environment @ X0)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @ X1)
% 0.76/0.80 | (in_environment @ X0 @ X1))),
% 0.76/0.80 inference('cnf', [status(esa)], [mp_time_point_occurs_26])).
% 0.76/0.80 thf(zip_derived_cl128, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i]:
% 0.76/0.80 (((X1) = (initial_FM_EP @ X0))
% 0.76/0.80 | ~ (environment @ X0)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @ X1)
% 0.76/0.80 | (in_environment @ X0 @ (initial_FM_EP @ X0)))),
% 0.76/0.80 inference('clc', [status(thm)], [zip_derived_cl119, zip_derived_cl4])).
% 0.76/0.80 thf(zip_derived_cl129, plain,
% 0.76/0.80 ((((sk2) = (initial_FM_EP @ sk1))
% 0.76/0.80 | ~ (environment @ sk1)
% 0.76/0.80 | (in_environment @ sk1 @ (initial_FM_EP @ sk1)))),
% 0.76/0.80 inference('s_sup-', [status(thm)], [zip_derived_cl12, zip_derived_cl128])).
% 0.76/0.80 thf(prove_l2_33, conjecture, (~( environment @ sk1 ))).
% 0.76/0.80 thf(zf_stmt_2, negated_conjecture, (environment @ sk1),
% 0.76/0.80 inference('cnf.neg', [status(esa)], [prove_l2_33])).
% 0.76/0.80 thf(zip_derived_cl11, plain, ( (environment @ sk1)),
% 0.76/0.80 inference('cnf', [status(esa)], [zf_stmt_2])).
% 0.76/0.80 thf(zip_derived_cl130, plain,
% 0.76/0.80 ((((sk2) = (initial_FM_EP @ sk1))
% 0.76/0.80 | (in_environment @ sk1 @ (initial_FM_EP @ sk1)))),
% 0.76/0.80 inference('demod', [status(thm)], [zip_derived_cl129, zip_derived_cl11])).
% 0.76/0.80 thf(mp_earliest_time_point_23, axiom,
% 0.76/0.80 (( ~( environment @ A ) ) |
% 0.76/0.80 ( ~( in_environment @ A @ ( initial_FM_EP @ A ) ) ) |
% 0.76/0.80 ( subpopulations @
% 0.76/0.80 first_movers @ efficient_producers @ A @ ( initial_FM_EP @ A ) ))).
% 0.76/0.80 thf(zip_derived_cl1, plain,
% 0.76/0.80 (![X0 : $i]:
% 0.76/0.80 (~ (environment @ X0)
% 0.76/0.80 | ~ (in_environment @ X0 @ (initial_FM_EP @ X0))
% 0.76/0.80 | (subpopulations @ first_movers @ efficient_producers @ X0 @
% 0.76/0.80 (initial_FM_EP @ X0)))),
% 0.76/0.80 inference('cnf', [status(esa)], [mp_earliest_time_point_23])).
% 0.76/0.80 thf(zip_derived_cl131, plain,
% 0.76/0.80 ((((sk2) = (initial_FM_EP @ sk1))
% 0.76/0.80 | ~ (environment @ sk1)
% 0.76/0.80 | (subpopulations @ first_movers @ efficient_producers @ sk1 @
% 0.76/0.80 (initial_FM_EP @ sk1)))),
% 0.76/0.80 inference('s_sup-', [status(thm)], [zip_derived_cl130, zip_derived_cl1])).
% 0.76/0.80 thf(zip_derived_cl11, plain, ( (environment @ sk1)),
% 0.76/0.80 inference('cnf', [status(esa)], [zf_stmt_2])).
% 0.76/0.80 thf(zip_derived_cl132, plain,
% 0.76/0.80 ((((sk2) = (initial_FM_EP @ sk1))
% 0.76/0.80 | (subpopulations @ first_movers @ efficient_producers @ sk1 @
% 0.76/0.80 (initial_FM_EP @ sk1)))),
% 0.76/0.80 inference('demod', [status(thm)], [zip_derived_cl131, zip_derived_cl11])).
% 0.76/0.80 thf(zip_derived_cl12, plain,
% 0.76/0.80 ( (subpopulations @ first_movers @ efficient_producers @ sk1 @ sk2)),
% 0.76/0.80 inference('cnf', [status(esa)], [zf_stmt_1])).
% 0.76/0.80 thf(zip_derived_cl2, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i]:
% 0.76/0.80 (~ (environment @ X0)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @ X1)
% 0.76/0.80 | (greater_or_equal @ X1 @ (initial_FM_EP @ X0)))),
% 0.76/0.80 inference('cnf', [status(esa)], [mp_earliest_time_point_24])).
% 0.76/0.80 thf(zip_derived_cl2, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i]:
% 0.76/0.80 (~ (environment @ X0)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @ X1)
% 0.76/0.80 | (greater_or_equal @ X1 @ (initial_FM_EP @ X0)))),
% 0.76/0.80 inference('cnf', [status(esa)], [mp_earliest_time_point_24])).
% 0.76/0.80 thf(zip_derived_cl12, plain,
% 0.76/0.80 ( (subpopulations @ first_movers @ efficient_producers @ sk1 @ sk2)),
% 0.76/0.80 inference('cnf', [status(esa)], [zf_stmt_1])).
% 0.76/0.80 thf(mp_positive_function_difference_25, axiom,
% 0.76/0.80 (( ~( environment @ A ) ) | ( ~( greater_or_equal @ B @ C ) ) |
% 0.76/0.80 ( ~( greater_or_equal @ D @ B ) ) |
% 0.76/0.80 ( ~( subpopulations @ first_movers @ efficient_producers @ A @ D ) ) |
% 0.76/0.80 ( ~( greater @
% 0.76/0.80 ( disbanding_rate @ first_movers @ C ) @
% 0.76/0.80 ( disbanding_rate @ efficient_producers @ C ) ) ) |
% 0.76/0.80 ( decreases @
% 0.76/0.80 ( difference @
% 0.76/0.80 ( disbanding_rate @ first_movers @ B ) @
% 0.76/0.80 ( disbanding_rate @ efficient_producers @ B ) ) ) |
% 0.76/0.80 ( greater @
% 0.76/0.80 ( disbanding_rate @ first_movers @ D ) @
% 0.76/0.80 ( disbanding_rate @ efficient_producers @ D ) ))).
% 0.76/0.80 thf(zip_derived_cl3, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i, X2 : $i, X3 : $i]:
% 0.76/0.80 (~ (environment @ X0)
% 0.76/0.80 | ~ (greater_or_equal @ X1 @ X2)
% 0.76/0.80 | ~ (greater_or_equal @ X3 @ X1)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @ X3)
% 0.76/0.80 | ~ (greater @ (disbanding_rate @ first_movers @ X2) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X2))
% 0.76/0.80 | (decreases @
% 0.76/0.80 (difference @ (disbanding_rate @ first_movers @ X1) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X1)))
% 0.76/0.80 | (greater @ (disbanding_rate @ first_movers @ X3) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X3)))),
% 0.76/0.80 inference('cnf', [status(esa)], [mp_positive_function_difference_25])).
% 0.76/0.80 thf(l3_22, axiom,
% 0.76/0.80 (( ~( environment @ A ) ) |
% 0.76/0.80 ( ~( subpopulations @ first_movers @ efficient_producers @ A @ B ) ) |
% 0.76/0.80 ( ~( decreases @
% 0.76/0.80 ( difference @
% 0.76/0.80 ( disbanding_rate @ first_movers @ B ) @
% 0.76/0.80 ( disbanding_rate @ efficient_producers @ B ) ) ) ))).
% 0.76/0.80 thf(zip_derived_cl0, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i]:
% 0.76/0.80 (~ (environment @ X0)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @ X1)
% 0.76/0.80 | ~ (decreases @
% 0.76/0.80 (difference @ (disbanding_rate @ first_movers @ X1) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X1))))),
% 0.76/0.80 inference('cnf', [status(esa)], [l3_22])).
% 0.76/0.80 thf(zip_derived_cl100, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i, X2 : $i, X3 : $i, X4 : $i, X5 : $i]:
% 0.76/0.80 (((difference @ (disbanding_rate @ first_movers @ X2) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X2))
% 0.76/0.80 != (difference @ (disbanding_rate @ first_movers @ X5) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X5)))
% 0.76/0.80 | (greater @ (disbanding_rate @ first_movers @ X3) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X3))
% 0.76/0.80 | ~ (greater @ (disbanding_rate @ first_movers @ X1) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X1))
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @ X3)
% 0.76/0.80 | ~ (greater_or_equal @ X3 @ X2)
% 0.76/0.80 | ~ (greater_or_equal @ X2 @ X1)
% 0.76/0.80 | ~ (environment @ X0)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X4 @ X5)
% 0.76/0.80 | ~ (environment @ X4))),
% 0.76/0.80 inference('dp-resolution', [status(thm)],
% 0.76/0.80 [zip_derived_cl3, zip_derived_cl0])).
% 0.76/0.80 thf(zip_derived_cl133, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i, X2 : $i, X3 : $i]:
% 0.76/0.80 (((difference @ (disbanding_rate @ first_movers @ X0) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X0))
% 0.76/0.80 != (difference @ (disbanding_rate @ first_movers @ X1) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X1)))
% 0.76/0.80 | (greater @ (disbanding_rate @ first_movers @ sk2) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ sk2))
% 0.76/0.80 | ~ (greater @ (disbanding_rate @ first_movers @ X2) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X2))
% 0.76/0.80 | ~ (greater_or_equal @ sk2 @ X0)
% 0.76/0.80 | ~ (greater_or_equal @ X0 @ X2)
% 0.76/0.80 | ~ (environment @ sk1)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X3 @ X1)
% 0.76/0.80 | ~ (environment @ X3))),
% 0.76/0.80 inference('s_sup-', [status(thm)], [zip_derived_cl12, zip_derived_cl100])).
% 0.76/0.80 thf(zip_derived_cl13, plain,
% 0.76/0.80 (~ (greater @ (disbanding_rate @ first_movers @ sk2) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ sk2))),
% 0.76/0.80 inference('cnf', [status(esa)], [zf_stmt_0])).
% 0.76/0.80 thf(zip_derived_cl11, plain, ( (environment @ sk1)),
% 0.76/0.80 inference('cnf', [status(esa)], [zf_stmt_2])).
% 0.76/0.80 thf(zip_derived_cl136, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i, X2 : $i, X3 : $i]:
% 0.76/0.80 (((difference @ (disbanding_rate @ first_movers @ X0) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X0))
% 0.76/0.80 != (difference @ (disbanding_rate @ first_movers @ X1) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X1)))
% 0.76/0.80 | ~ (greater @ (disbanding_rate @ first_movers @ X2) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X2))
% 0.76/0.80 | ~ (greater_or_equal @ sk2 @ X0)
% 0.76/0.80 | ~ (greater_or_equal @ X0 @ X2)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X3 @ X1)
% 0.76/0.80 | ~ (environment @ X3))),
% 0.76/0.80 inference('demod', [status(thm)],
% 0.76/0.80 [zip_derived_cl133, zip_derived_cl13, zip_derived_cl11])).
% 0.76/0.80 thf(zip_derived_cl153, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i, X2 : $i, X3 : $i]:
% 0.76/0.80 (~ (subpopulations @ first_movers @ efficient_producers @ X0 @ sk2)
% 0.76/0.80 | ~ (environment @ X0)
% 0.76/0.80 | ((difference @
% 0.76/0.80 (disbanding_rate @ first_movers @ (initial_FM_EP @ X0)) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ (initial_FM_EP @ X0)))
% 0.76/0.80 != (difference @ (disbanding_rate @ first_movers @ X1) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X1)))
% 0.76/0.80 | ~ (greater @ (disbanding_rate @ first_movers @ X2) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X2))
% 0.76/0.80 | ~ (greater_or_equal @ (initial_FM_EP @ X0) @ X2)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X3 @ X1)
% 0.76/0.80 | ~ (environment @ X3))),
% 0.76/0.80 inference('s_sup-', [status(thm)], [zip_derived_cl2, zip_derived_cl136])).
% 0.76/0.80 thf(zip_derived_cl192, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i, X2 : $i, X3 : $i]:
% 0.76/0.80 (~ (subpopulations @ first_movers @ efficient_producers @ X0 @
% 0.76/0.80 (initial_FM_EP @ X1))
% 0.76/0.80 | ~ (environment @ X0)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X1 @ sk2)
% 0.76/0.80 | ~ (environment @ X1)
% 0.76/0.80 | ((difference @
% 0.76/0.80 (disbanding_rate @ first_movers @ (initial_FM_EP @ X1)) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ (initial_FM_EP @ X1)))
% 0.76/0.80 != (difference @ (disbanding_rate @ first_movers @ X2) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X2)))
% 0.76/0.80 | ~ (greater @
% 0.76/0.80 (disbanding_rate @ first_movers @ (initial_FM_EP @ X0)) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ (initial_FM_EP @ X0)))
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X3 @ X2)
% 0.76/0.80 | ~ (environment @ X3))),
% 0.76/0.80 inference('s_sup-', [status(thm)], [zip_derived_cl2, zip_derived_cl153])).
% 0.76/0.80 thf(a8_31, axiom,
% 0.76/0.80 (( ~( environment @ A ) ) |
% 0.76/0.80 ( greater @
% 0.76/0.80 ( disbanding_rate @ first_movers @ ( initial_FM_EP @ A ) ) @
% 0.76/0.80 ( disbanding_rate @ efficient_producers @ ( initial_FM_EP @ A ) ) ))).
% 0.76/0.80 thf(zip_derived_cl9, plain,
% 0.76/0.80 (![X0 : $i]:
% 0.76/0.80 (~ (environment @ X0)
% 0.76/0.80 | (greater @
% 0.76/0.80 (disbanding_rate @ first_movers @ (initial_FM_EP @ X0)) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ (initial_FM_EP @ X0))))),
% 0.76/0.80 inference('cnf', [status(esa)], [a8_31])).
% 0.76/0.80 thf(zip_derived_cl235, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i, X2 : $i, X3 : $i]:
% 0.76/0.80 (~ (environment @ X3)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X3 @ X2)
% 0.76/0.80 | ((difference @
% 0.76/0.80 (disbanding_rate @ first_movers @ (initial_FM_EP @ X1)) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ (initial_FM_EP @ X1)))
% 0.76/0.80 != (difference @ (disbanding_rate @ first_movers @ X2) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ X2)))
% 0.76/0.80 | ~ (environment @ X1)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X1 @ sk2)
% 0.76/0.80 | ~ (environment @ X0)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @
% 0.76/0.80 (initial_FM_EP @ X1)))),
% 0.76/0.80 inference('clc', [status(thm)], [zip_derived_cl192, zip_derived_cl9])).
% 0.76/0.80 thf(zip_derived_cl239, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i]:
% 0.76/0.80 (~ (subpopulations @ first_movers @ efficient_producers @ X1 @
% 0.76/0.80 (initial_FM_EP @ X0))
% 0.76/0.80 | ~ (environment @ X1)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @ sk2)
% 0.76/0.80 | ~ (environment @ X0)
% 0.76/0.80 | ((difference @
% 0.76/0.80 (disbanding_rate @ first_movers @ (initial_FM_EP @ X0)) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ (initial_FM_EP @ X0)))
% 0.76/0.80 != (difference @
% 0.76/0.80 (disbanding_rate @ first_movers @ (initial_FM_EP @ X0)) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ (initial_FM_EP @ X0))))
% 0.76/0.80 | ~ (environment @ X1))),
% 0.76/0.80 inference('eq_fact', [status(thm)], [zip_derived_cl235])).
% 0.76/0.80 thf(zip_derived_cl240, plain,
% 0.76/0.80 (![X0 : $i, X1 : $i]:
% 0.76/0.80 (~ (environment @ X0)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @ sk2)
% 0.76/0.80 | ~ (environment @ X1)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X1 @
% 0.76/0.80 (initial_FM_EP @ X0)))),
% 0.76/0.80 inference('simplify', [status(thm)], [zip_derived_cl239])).
% 0.76/0.80 thf(zip_derived_cl246, plain,
% 0.76/0.80 (![X0 : $i]:
% 0.76/0.80 (~ (environment @ sk1)
% 0.76/0.80 | ~ (environment @ X0)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @
% 0.76/0.80 (initial_FM_EP @ sk1)))),
% 0.76/0.80 inference('s_sup-', [status(thm)], [zip_derived_cl12, zip_derived_cl240])).
% 0.76/0.80 thf(zip_derived_cl11, plain, ( (environment @ sk1)),
% 0.76/0.80 inference('cnf', [status(esa)], [zf_stmt_2])).
% 0.76/0.80 thf(zip_derived_cl249, plain,
% 0.76/0.80 (![X0 : $i]:
% 0.76/0.80 (~ (environment @ X0)
% 0.76/0.80 | ~ (subpopulations @ first_movers @ efficient_producers @ X0 @
% 0.76/0.80 (initial_FM_EP @ sk1)))),
% 0.76/0.80 inference('demod', [status(thm)], [zip_derived_cl246, zip_derived_cl11])).
% 0.76/0.80 thf(zip_derived_cl254, plain,
% 0.76/0.80 ((((sk2) = (initial_FM_EP @ sk1)) | ~ (environment @ sk1))),
% 0.76/0.80 inference('s_sup-', [status(thm)], [zip_derived_cl132, zip_derived_cl249])).
% 0.76/0.80 thf(zip_derived_cl11, plain, ( (environment @ sk1)),
% 0.76/0.80 inference('cnf', [status(esa)], [zf_stmt_2])).
% 0.76/0.80 thf(zip_derived_cl256, plain, (((sk2) = (initial_FM_EP @ sk1))),
% 0.76/0.80 inference('demod', [status(thm)], [zip_derived_cl254, zip_derived_cl11])).
% 0.76/0.80 thf(zip_derived_cl9, plain,
% 0.76/0.80 (![X0 : $i]:
% 0.76/0.80 (~ (environment @ X0)
% 0.76/0.80 | (greater @
% 0.76/0.80 (disbanding_rate @ first_movers @ (initial_FM_EP @ X0)) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ (initial_FM_EP @ X0))))),
% 0.76/0.80 inference('cnf', [status(esa)], [a8_31])).
% 0.76/0.80 thf(zip_derived_cl264, plain,
% 0.76/0.80 ((~ (environment @ sk1)
% 0.76/0.80 | (greater @ (disbanding_rate @ first_movers @ sk2) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ sk2)))),
% 0.76/0.80 inference('s_sup+', [status(thm)], [zip_derived_cl256, zip_derived_cl9])).
% 0.76/0.80 thf(zip_derived_cl11, plain, ( (environment @ sk1)),
% 0.76/0.80 inference('cnf', [status(esa)], [zf_stmt_2])).
% 0.76/0.80 thf(zip_derived_cl280, plain,
% 0.76/0.80 ( (greater @ (disbanding_rate @ first_movers @ sk2) @
% 0.76/0.80 (disbanding_rate @ efficient_producers @ sk2))),
% 0.76/0.80 inference('demod', [status(thm)], [zip_derived_cl264, zip_derived_cl11])).
% 0.76/0.80 thf(zip_derived_cl294, plain, ($false),
% 0.76/0.80 inference('demod', [status(thm)], [zip_derived_cl13, zip_derived_cl280])).
% 0.76/0.80
% 0.76/0.80 % SZS output end Refutation
% 0.76/0.80
% 0.76/0.80
% 0.76/0.80 % Terminating...
% 0.76/0.86 % Runner terminated.
% 0.76/0.87 % Zipperpin 1.5 exiting
%------------------------------------------------------------------------------