LAUSR

In this paper, we study the gravitational waveforms, polarizations and radiation powers of the first relativistic triple systems PSR J0337 + 1715, observed in 2014, by using the post-Newtonian approximations to their lowest order. Although they cannot be observed either by current or next generation of the detectors, they do provide useful information to test different theories of gravity. In particular, we carry out the studies in three different theories, general relativity (GR), Brans-Dicke (BD) gravity, and Einstein-aether ($\ae$) theory. The tensor modes $h_{+}$ and $h_{\times}$ exist in all three theories and have almost equal amplitudes. Their frequencies are all peaked at two locations, $ f^{(+, \times)}_1 \simeq 0.0686656 \mu$Hz and $ f^{(+, \times)}_2 \simeq 14.2138 \mu$Hz, which are about twice of the outer and inner orbital frequencies of the triple system, as predicted in GR. In $\ae$-theory, all the six polarization modes are different from zero, but the breathing $h_b$ and longitudinal $h_L$ modes are not independent and also peaked at two frequencies, but at the frequencies, $ f^{(b, L, \ae)}_{1} \simeq 0.0457771 \mu$Hz and $f^{(b, L, \ae)}_{ 2} \simeq 7.09545 \mu$Hz. A similar phenomenon is also observed in BD gravity, in which only the three modes $h_{+},\; h_{\times}$ and $h_{b}$ exit. We also study the radiation powers, and find that the quadrupole emission in each of the three theories has almost the same amplitude, but the dipole emission can be as big as the quadrupole emission in $\ae$-theory. This can provide a very promising window to obtain severe constraints on $\ae$-theory by the multi-band gravitational wave astronomy.