CCL:G: TDDFT in gaussian

 Sent to CCL by: Jens Spanget-Larsen [spanget^^ruc.dk]
 Dear Agalya Govindasamy,
maybe you already solved your problem. But nevertheless, for a closed shell species, it is easy to calculate the percentage contributions from the coefficients printed by a Gaussian TDDFT run. The coefficients refer to micro-configurations (not spin adapted). If you want the percentage contribution from the pertinent singlet configuration, you must square the printed coefficient and multiply it by 2 x 100. For instance, the contribution from the 129 -> 138 excitation in the first of your examples amounts to 
 0.45069^2 x 2 x 100 = 40.62%.
 In your second example, you get for the 130 -> 132 excitation
 0.67417^2 x 2 x 100 = 90.90%.
Please note that Gaussian by default prints only contributions larger than a certain treshold. There is an IOP input parameter that leads to printing also of smaller contributions, but I do not have it at hand. 
 Good Luck!
 Jens >--<
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 Agalya Govindasamy agalya81{}gmail.com wrote:
 
 Sent to CCL by: "Agalya  Govindasamy" [agalya81-x-gmail.com]
 Dear CCL users,
 I would like to know about calculating the precentage contribution of excitation
 coefficients given in the TDDFT output.
 For example, the following excitation shows mixture of transitions with
 different excitation coefficients.
 Excited State  31:	Singlet-A	3.6351 eV	341.07 nm	f=0.0001
 119 ->132	0.11466
 124 ->138	0.16417
 124 ->140	-0.16712
 129 ->138	0.45069
 129 ->140	-0.3978
 129 ->141	-0.12337
 130 ->136	-0.10225
I have seen in some journals, that they have mentioned the coefficients as percentage. Here since there are many transitions, could anyone can please tell me how to calculate the percentage of the coefficients. This may be a stupid question. Does everyone divide the particular coefficient divided by the sum of all the coefficients and then multiplied by 100 to get the percentage value? 
 If that is correct, then how to get percentage value of the coefficient for
 excitations like the following case
 Excited State   1:	Singlet-A	1.5328 eV	808.90 nm	f=0.0287
 130 ->132	0.67417
can i mention it as 100%. 
 Thankyou in adavnce