Sensitive magnetometers find wide range of applications, from tests of fundamental symmetries to measurements of biological magnetic fields. Low temperature SQUID detector presently hold the record as the most sensitive magnetometers with a noise level of about 1fT / Hz . However, its huge bulk due to the complex structure and high cost of cryogenic cooling confine its applications. Recently years, Alkali-metal magnetometers using Potassium and Rubidium approach this level of sensitivity. The mechanism of atomic magnetometers relies on a measurement of Larmor precession of spin-polarized atoms in a magnetic field. The fundamental noise is limited by the quantum shot noise which is related to the transverse relaxation time of the spin polarized atoms.The atomic magnetometers operating near zero field which eliminates spin exchange collision as the source of relaxation shows a fundamental noise limit which is about 0.3 fT / Hz . To block out environmental tray field, these systems apply μ -metal shield or Helmholtz coil compensate system. This thesis proposes an improved version of the un-shielded system in reference : the optical detection of the signals is processed by a DAQ card and a computer to simplify the system, an EO stabilizer is introduced to lower the optical noise level in the detection, and a improved method is developed to reduce the time spent in field compensating.