An apparatus and method for measuring a local acceleration of gravity includes releasing a ferrous rod having a regular alternating pattern of reflective and non-reflective portions on a surface thereof from an electromagnetic holder so that the rod falls with a substantially vertical acceleration and substantially no angular velocity about a center of mass of the rod. The falling rod is illuminated with a light emitting diode (LED) configured to emit infrared (IR) light, and IR light emitted by the LED and reflected by the falling rod is detected with a photodiode. A two-state signal is generated corresponding to an illumination state of the photodiode by the reflected IR light. Times of transitions between the two states in the generated signal are calculated to determine kinematic data, and the kinematic data is fitted to a predetermined curve to calculate a local acceleration of gravity.

A system for gravity measurement includes one or more atom sources, two or more laser beams, and a polarizing beamsplitter and a retro-reflection prism assembly. The one or more atom sources is to provide three ensembles of atoms. The two or more laser beams is to cool or interrogate the three ensembles of atoms. The polarizing beamsplitter and the retro-reflection prism assembly are in a racetrack configuration. The racetrack configuration routes the two or more laser beams in opposing directions around a loop topology, intersecting the three ensembles of atoms with appropriate polarizations chosen for cooling or interferometer interrogation. The three ensembles of atoms are positioned coaxially when interrogated.

A system for gravity measurement includes one or more atom sources, two or more laser beams, and a polarizing beamsplitter and a retro-reflection prism assembly. The one or more atom sources is to provide three ensembles of atoms. The two or more laser beams is to cool or interrogate the three ensembles of atoms. The polarizing beamsplitter and the retro-reflection prism assembly are in a racetrack configuration. The racetrack configuration routes the two or more laser beams in opposing directions around a loop topology, intersecting the three ensembles of atoms with appropriate polarizations chosen for cooling or interferometer interrogation. The three ensembles of atoms are positioned coaxially when interrogated.

An apparatus and method for measuring a local acceleration of gravity includes releasing a ferrous rod having a regular alternating pattern of reflective and non-reflective portions on a surface thereof from an electromagnetic holder so that the rod falls with a substantially vertical acceleration and substantially no angular velocity about a center of mass of the rod. The falling rod is illuminated with a light emitting diode (LED) configured to emit infrared (IR) light, and IR light emitted by the LED and reflected by the falling rod is detected with a photodiode. A two-state signal is generated corresponding to an illumination state of the photodiode by the reflected IR light. Times of transitions between the two states in the generated signal are calculated to determine kinematic data, and the kinematic data is fitted to a predetermined curve to calculate a local acceleration of gravity.

An apparatus and method for measuring a local acceleration of gravity includes releasing a ferrous rod having a regular alternating pattern of reflective and non-reflective portions on a surface thereof from an electromagnetic holder so that the rod falls with a substantially vertical acceleration and substantially no angular velocity about a center of mass of the rod. The falling rod is illuminated with a light emitting diode (LED) configured to emit infrared (IR) light, and IR light emitted by the LED and reflected by the falling rod is detected with a photodiode. A two-state signal is generated corresponding to an illumination state of the photodiode by the reflected IR light. Times of transitions between the two states in the generated signal are calculated to determine kinematic data, and the kinematic data is fitted to a predetermined curve to calculate a local acceleration of gravity.

An apparatus and method for measuring a local acceleration of gravity includes releasing a ferrous rod having a regular alternating pattern of reflective and non-reflective portions on a surface thereof from an electromagnetic holder so that the rod falls with a substantially vertical acceleration and substantially no angular velocity about a center of mass of the rod. The falling rod is illuminated with a light emitting diode (LED) configured to emit infrared (IR) light, and IR light emitted by the LED and reflected by the falling rod is detected with a photodiode. A two-state signal is generated corresponding to an illumination state of the photodiode by the reflected IR light. Times of transitions between the two states in the generated signal are calculated to determine kinematic data, and the kinematic data is fitted to a predetermined curve to calculate a local acceleration of gravity.

An apparatus and method for measuring a local acceleration of gravity includes releasing a ferrous rod having a regular alternating pattern of reflective and non-reflective portions on a surface thereof from an electromagnetic holder so that the rod falls with a substantially vertical acceleration and substantially no angular velocity about a center of mass of the rod. The falling rod is illuminated with a light emitting diode (LED) configured to emit infrared (IR) light, and IR light emitted by the LED and reflected by the falling rod is detected with a photodiode. A two-state signal is generated corresponding to an illumination state of the photodiode by the reflected IR light. Times of transitions between the two states in the generated signal are calculated to determine kinematic data, and the kinematic data is fitted to a predetermined curve to calculate a local acceleration of gravity.

An apparatus for driving atoms of an atom cloud into a targeted quantum state is provided, the apparatus comprising: an atom source for releasing a cloud of atoms to be driven into a targeted quantum state; a laser system configured to generate a laser beam to be directed onto the atom cloud in use, the laser beam having a frequency corresponding to a resonant frequency of an atomic transition for exciting the atoms into the targeted quantum state; a modulator configured to, in use, modulate the frequency of the laser beam responsive to an input signal; a waveform generator coupled to the modulator and configured to, in use, generate an input signal for the modulator, wherein the input signal is arranged to cause the modulator to modulate the laser light to generate a comb of frequencies around the resonant frequency of the atomic transition, the frequency comb including a plurality of peaks, each peak being separated by a frequency spacing, ??, that is determined based on a Rabi frequency, ?, of the atomic transition to drive atoms of the atom cloud into a targeted quantum state.

The ball-loading device for free-fall experiments includes an inlet tube and a shell. The first end of the shell is connected to the inlet tube, and the shell has a ball channel. A ball outlet is located at the second end of the shell, with the first end of the inlet shell positioned higher than the second end. Additionally, a bracket is rotatably connected to the shell and has a first blocking part and a second blocking part. As the bracket rotates around the shell, the first blocking part is switched to block the ball outlet, or the second blocking part is switched to block the ball channel. This device provided by the present disclosure allows automatic loading and resetting of the balls used in free fall experiments, thereby improving experimental efficiency.

The ball-loading device for free-fall experiments includes an inlet tube and a shell. The first end of the shell is connected to the inlet tube, and the shell has a ball channel. A ball outlet is located at the second end of the shell, with the first end of the inlet shell positioned higher than the second end. Additionally, a bracket is rotatably connected to the shell and has a first blocking part and a second blocking part. As the bracket rotates around the shell, the first blocking part is switched to block the ball outlet, or the second blocking part is switched to block the ball channel. This device provided by the present disclosure allows automatic loading and resetting of the balls used in free fall experiments, thereby improving experimental efficiency.