In digital communication systems the use of filters
that fulfill the first Nyquist criterion (Nyquist-I), guarantees
that a sequence of pulses will not be affected by inter-symbol
interference (ISI) if the receiver samples signals at optimum and
uniformly spaced instants. In this manuscript the Nyquist-I pulse,
called exponential linear pulse (ELP), is evaluated in the time and
frequency domain using different evaluation tools and compared
with other existing pulses. The eye diagram is simulated in
presence of time sampling errors and the approximated average
bit error rate (BER) is computed considering the ideal and
truncated version of the pulses. Finally, the spectral energy
distribution and spectral regrowth of the pulses are presented
for comparison purposes. Numerical results show that the ELP
outperforms other existing pulses in terms of the eye diagram
opening and BER, evaluated for various symbol timing errors
and roll-off factors. However, the good performance of the ELP
in the time domain is at the expenses of introduction of out-ofband
radiation compared to the traditional Raised Cosine pulse;
therefore, a trade-off between BER and out-of-band radiation
exists.