The dynamic rheological properties of poly(ethylene terphthalate) melt were determined as functions of angular frequency, temperature, time, and shear starain, respectively. All measurements were made in Rheometrics Dynamic Spectrometer with oscillatory parallel plate. Under the conditions of 290$^{circ}C$ and 15% shear strain the complex viscosity was independent of the angular frequency below 40 radians/sec, thus indicating Newtonian in behavior, but it decreased with increasing angular frequency above 40 radians/sec, indicating non-Newtonian. The experimental data of tan $delta$ coincided fairly well with the data calculated with the Maxwell viscoelastic model when the relaxation time was 1.7${ imes}$10-3sec. The complex viscosity followed the Andrade or Arrhenius equation except at low temperatures, i.e., below 228$^{circ}C$ when the Andrade equation was matched to the experimental value at 277$^{circ}C$ and the value of activation energy was 13.5 Kcal/mole. The interpretation of increase in storage modulus, loss modulus, and complex viscosity and decrease in tan$delta$ with the lapse of time for a given frequency, temperature, and shear strain was discussed. All rheological properties showed no variations with shear strain up to 28 percentages for a given temperature and angular frequency.