[\(((tau to_power 5) / (sqrt 5)) + (1 / 2))/] = 5 by FIB_NUM4:18, LFIB5;
then 5 - (1 / 2) <= (((tau to_power 5) / (sqrt 5)) + (1 / 2)) - (1 / 2) by XREAL_1:9, INT_1:def 6;
then (9 / 2) * (sqrt 5) <= ((tau to_power 5) / (sqrt 5)) * (sqrt 5) by XREAL_1:64;
then (9 / 2) * (sqrt 5) <= (tau to_power 5) / ((sqrt 5) / (sqrt 5)) by XCMPLX_1:81;
then WEQ: (9 / 2) * (sqrt 5) <= (tau to_power 5) / 1 by XCMPLX_1:60;
((9 / 2) * (sqrt 5)) - 10 = (((9 * (sqrt 5)) - 20) / 2) / (((9 * (sqrt 5)) + 20) / ((9 * (sqrt 5)) + 20)) by XCMPLX_1:51
.= (((9 * (sqrt 5)) - 20) / (((9 * (sqrt 5)) + 20) / ((9 * (sqrt 5)) + 20))) / 2 by XCMPLX_1:48
.= ((((9 * (sqrt 5)) - 20) * ((9 * (sqrt 5)) + 20)) / ((9 * (sqrt 5)) + 20)) / 2 by XCMPLX_1:77
.= (((81 * ((sqrt 5) ^2)) - 400) / ((9 * (sqrt 5)) + 20)) / 2
.= (((81 * 5) - 400) / ((9 * (sqrt 5)) + 20)) / 2 by SQUARE_1:def 2
.= (5 / ((9 * (sqrt 5)) + 20)) / 2 ;
then 10 < (((9 / 2) * (sqrt 5)) - 10) + 10 by XREAL_1:29;
then 10 < tau to_power 5 by WEQ, XXREAL_0:2;
then log (tau,10) < log (tau,(tau to_power 5)) by POWER:57, THTU;
then log (tau,10) < 5 * (log (tau,tau)) by POWER:55, THTU;
then log (tau,10) < 5 * 1 by POWER:52, THTU;
hence log (tau,10) < 5 ; :: thesis: verum