Your search keyword '"Suzuyama, Tomonari"' showing total 16 results

1. Demonstration of the nearly continuous operation of an 171Yb optical lattice clock for half a year.

Author

Kobayashi, Takumi, Akamatsu, Daisuke, Hosaka, Kazumoto, Hisai, Yusuke, Wada, Masato, Inaba, Hajime, Suzuyama, Tomonari, Hong, Feng-Lei, and Yasuda, Masami

Published

2020

2. Potential for improving the local realization of coordinated universal time with a convolutional neural network.

Author

Tanabe, Takehiko, Ye, Jiaxing, Suzuyama, Tomonari, Kobayashi, Takumi, Yamaguchi, Yu, and Yasuda, Masami

Subjects

ARTIFICIAL neural networks, DEEP learning, KALMAN filtering

Abstract

The time difference between coordinated universal time (UTC) and a hydrogen maser, which is a master oscillator for the local realization of UTC at the National Metrology Institute of Japan (NMIJ), has been predicted by using one of the deep learning techniques called a one-dimensional convolutional neural network (1D-CNN). Regarding the prediction result obtained by the 1D-CNN, we have observed improvement in the accuracy of prediction compared with that obtained by the Kalman filter. Although more investigations are required to conclude that the 1D-CNN can work as a good predictor, the present results suggest that the computational approach based on the deep learning technique may become a versatile method for improving the synchronous accuracy of UTC(NMIJ) relative to UTC. [ABSTRACT FROM AUTHOR]

Published

2019

3. Uncertainty Evaluation of an 171Yb Optical Lattice Clock at NMIJ.

Author

Kobayashi, Takumi, Akamatsu, Daisuke, Hisai, Yusuke, Tanabe, Takehiko, Inaba, Hajime, Suzuyama, Tomonari, Hong, Feng-Lei, Hosaka, Kazumoto, and Yasuda, Masami

Subjects

ULTRASONIC imaging, MICROELECTROMECHANICAL systems, PARTICLE image velocimetry, PICOSECOND pulses, RADIO frequency

Abstract

We report an uncertainty evaluation of an 171Yb optical lattice clock with a total fractional uncertainty of $3.6\times 10^{-16}$ , which is mainly limited by the lattice-induced light shift and the blackbody radiation shift. Our evaluation of the lattice-induced light shift, the density shift, and the second-order Zeeman shift is based on an interleaved measurement where we measure the frequency shift using the alternating stabilization of a clock laser to the 6s2 1S0–6s6p 3P0 clock transition with two different experimental parameters. In the present evaluation, the uncertainties of two sensitivity coefficients for the lattice-induced hyperpolarizability shift $d$ incorporated in a widely used light shift model by RIKEN and the second-order Zeeman shift $a_{Z}$ are improved compared with the uncertainties of previous coefficients. The hyperpolarizability coefficient $d$ is determined by investigating the trap potential depth and the light shifts at the lattice frequencies near the two-photon transitions 6s6p3P0–6s8p3P0, 6s8p3P2, and 6s5f3F2. The obtained values are $d=-1.1(4)\,\,{\mu }$ Hz and $a_{Z}=-6.6(3)$ Hz/mT2. These improved coefficients should reduce the total systematic uncertainties of Yb lattice clocks at other institutes. [ABSTRACT FROM AUTHOR]

Published

2018

4. A Precise Frequency Comparison System Using an Optical Carrier.

Author

WADA, MASATO, WATABE, KEN‐ICHI, OKUBO, SHO, SUZUYAMA, TOMONARI, HONG, FENG‐LEI, and AMEMIYA, MASAKI

Subjects

OPTICAL fibers, INTERFEROMETERS, FREQUENCY standards, FREQUENCY stability, OPTICAL lattices

Abstract

SUMMARY We have investigated the performance of an optical carrier transfer system for remote comparison of optical clocks. In the frequency transfer system, technical problems and fundamental principles limit coherent transfer on a long-haul optical fiber. They contribute to noise processes that come from the propagation delay in the fiber, the design of the interferometer, burst length fluctuations of the fiber, asymmetrical propagation characteristics, and so on. The feasibility of a full optical link with high stability is discussed. Phase detection with a high degree of precision and cancelation of the fiber-induced noise on the round-trip light are achieved with a well-known standard technique using an all-fiber-based interferometer. We report the characteristics of these noise processes with results on a spooled fiber. The Allan deviation of the compensated link which is extended to 90 km reaches 5 × 10−18, close to the theoretical limit imposed by the delay-unsuppressed fiber noise at an averaging time of 103 s. [ABSTRACT FROM AUTHOR]

Published

2015

5. Development of radio seeing monitor using LEO satellite beacons.

Author

Nishio, Masanori, Suzuyama, Tomonari, Kohashiguchi, Hiroshi, Miyazaki, Tomoyuki, Sumino, Yoshio, Ando, Takafusa, Hirata, Masako, and Liu, Qinghui

Published

2002

6. System for precise dissemination of frequency standard via optical fiber.

Author

Amemiya, Masaki, Imae, Michito, Fujii, Yasuhisa, Suzuyama, Tomonari, Naito, Takashi, Urakawa, Junji, Ebihara, Kiyokazu, and Terunuma, Nobuhiro

Subjects

FREQUENCY standards, OPTICAL fibers, OPTICAL amplifiers, WAVELENGTH division multiplexing, FREQUENCY stability

Abstract

A precise frequency dissemination system using optical fiber is studied. The purpose of the system is to transmit a frequency standard with little deterioration to many distant users. It is composed of a phase compensation transmitter, bidirectional optical amplifiers, optical amplified distributor, and receiver. The goal of the system is to achieve stable transmission of hydrogen maser-class signals. For short-term stability, the required optical received power to realize an Allan deviation of 1 × 10-13 (average time of 1 s) is shown. For long-term stability, a new compensation method using a third wavelength transmission is effective to suppress phase fluctuation induced by temperature changes in the fiber. Experimental results show a stability of 8 × 10-17 at 105 s in a fiber link of 160 km in all with one bidirectional amplifier. © 2012 Wiley Periodicals, Inc. Electron Comm Jpn, 95(3): 45-54, 2012; Published online in Wiley Online Library (). DOI 10.1002/ecj.10372 [ABSTRACT FROM AUTHOR]

Published

2012

7. Precise Frequency Comparison System Using Bidirectional Optical Amplifiers.

Author

Amemiya, Masaki, Imae, Michito, Fujii, Yasuhisa, Suzuyama, Tomonari, Feng-Lei Hong, and Takamoto, Masao

Subjects

OPTICAL amplifiers, WAVELENGTH division multiplexing, FREQUENCY standards, FREQUENCY spectra, TELECOMMUNICATION systems, OPTICAL losses, FREQUENCY stability, OPTICAL fibers

Abstract

Precise frequency comparisons are becoming more urgent given the recent rapid progress in next-generation frequency standards. This paper describes a new type of bidirectional optical amplifier that overcomes the fiber loss limits that have prevented accurate frequency comparisons between widely separated places; such comparison is realized by bidirectionally transmitting wavelength-division-multiplexed (WDM) signals along a single fiber. The proposed optical amplifier has an optical isolator in each two-way channel divided by wavelength filters to suppress the optical reflection that causes amplification instability. The additional insertion optical loss due to this method is about 1.5 dB. The optical gain greater than 30 dB is obtained for both signals with good optical isolation of 65 dB. A radio-frequency reference signal can directly be sent by simple intensity modulation and direct detection (IM-DD) devices in the 1550-nm region widely used in telecommunication networks. Phase comparisons of the received signals and the frequency standards at each terminal are used for frequency comparisons. The amplifier is tested in the field using two hydrogen masers. A 120-km fiber with loss of 52.5 dB is used to connect the National Metrology Institute of Japan (NMIJ) to the University of Tokyo. Because of this loss, an amplifier is needed to realize sufficient receiving power. The frequency stability of the system with a 10-MHz direct transmission is evaluated by returning the optical signal from a halfway point [55 km from the NMIJ] where the amplifier is installed. The result is 2.6 x 10-16 (Allan deviation) with the averaging time of 7 x 104 s. The laboratory result is 8.7 x 10-17 (τ = 4 x 104 s). The amplifier's long-term stability is promising for stable frequency dissemination in addition to precise frequency comparisons. [ABSTRACT FROM AUTHOR]

Published

2010

8. Remote Synchronization Experiments for Quasi-Senith Satellite System Using Current Geostationary Satellites.

Author

Iwata, Toshiaki, Suzuyama, Tomonari, Imae, Michito, and Hashibe, Yuji

Subjects

ORBITAL spacing of geostationary satellites, CRYSTAL oscillators, ENERGY consumption, SYNCHRONIZATION, ATOMIC clocks, TECHNOLOGICAL innovations

Abstract

The remote synchronization system for the onboard crystal oscillator (RESSOX) realizes accurate synchronization between an atomic clock at a ground station and the QZSS onboard crystal oscillator, reduces overall cost and satellite power consumption, as well as onboard weight and volume, and is expected to have a longer lifetime than a system with onboard atomic clocks. Since a QZSS does not yet exist, we have been conducting synchronization experiments using geostationary earth orbit satellites (JCSAT- 1B or Intelsat-4) to confirm that RESSOX is an excellent system for timing synchronization. JCSAT-1B, the elevation angle of which is 46.5 degrees at our institute, is little affected by tropospheric delay, whereas Intelsat-4, the elevation angle of which is 7.9 degrees, is significantly affected. The experimental setup and the results of uplink experiments and feedback experiments using mainly Intelsat-4 are presented. The results show that synchronization within 10 ns is realized. [ABSTRACT FROM AUTHOR]

Published

2010

9. Simple Time and Frequency Dissemination Method Using Optical Fiber Network.

Author

Amemiya, Masaki, Imae, Michito, Fujii, Yasuhisa, Suzuyama, Tomonari, and Ohshima, Shin-Ichi

Subjects

DATA transmission systems, DIGITAL signal processing, DIGITAL electronics, DIGITAL media, SIGNAL generators, ELECTRIC oscillators, ELECTRONIC appliance testing, OPTICAL waveguides, OPTICAL communications

Abstract

This paper describes a simple and cost-effective method of frequency dissemination. In current digital communication networks, node clocks are hierarchically synchronized to the atomic master clock through fiber links. This synchronized network is used as an intermediate link for remote calibration services like the global positioning system common-view method. A prototype reference signal generator has been developed for recovering the communication clock signal and synthesizing a 10-MHz signal from it. The generator output frequency at the client site can be traced to coordinated universal time (UTC) National Metrology Institute of Japan (NMIJ) with some uncertainty, depending on the stability of the node clocks and the distance from the master clock. The stability performance of the generated reference signal has been tested at Okinawa-the farthest prefecture from Tokyo, where the master clock is located (baseline distance of 1500 km). The primary rate (1.544 MHz) for telecommunication services was chosen for the 10-MHz signal generation in the experiment. A sinusoidal phase fluctuation within a one-day period is dominantly observed. This fluctuation is mainly caused by fiber expansion and contraction due to normal daily temperature changes. It degrades the stability (Allan deviation) to the level of 5 × 10-13 τ = 40 000 s, which is almost half a day). However, the major part of the phase fluctuation can be canceled by averaging a full day's data. In this case, the Allan deviation becomes 1 ×-13 which is obtained at Okinawa over ten consecutive days of measurement. The worst average frequency offset relative to UTC (NMIJ) (one-day averaging) is -6.3 × 10-13. The results indicate that this method promises to be suitable for most applications, providing an uncertainty of less than 1 × 10-12 at an averaging time of one day. [ABSTRACT FROM AUTHOR]

Published

2008

10. Remote Synchronization Simulation of Onboard Crystal Oscillator for QZSS Using L1 /L2/L5 Signals for Error Adjustment.

Author

Iwata, Toshiaki, Imae, Michito, Suzuyama, Tomonari, Hashibe, Yuji, Fukushima, Satoshi, Iwasaki, Akira, Kokubu, Kenji, Tappero, Fabrizio, and Dempster, Andrew G.

Subjects

ARTIFICIAL satellites in navigation, SYNCHRONIZATION, CRYSTAL oscillators, GLOBAL Positioning System, NAVIGATION equipment, SIGNAL processing, TIME measurements

Abstract

The article discusses an error adjustment process for the remote synchronization of the Japanese quasi-zenith satellite system's (QZSS') onboard crystal oscillator. For the synchronization process, three different frequency positioning signals (L1/L2/L5) are used. The QZSS, which is a three-satellite navigation/positioning system, was developed to enhance the positioning performance of the global positioning system (GPS) that is currently used in urban areas. The National Institute of Advanced Industrial Science and Technology, Japan, has planned a new time-keeping method of the QZSS, which is called the remote synchronization system for an onboard crystal oscillator.

Published

2008

11. Observation Site Atmospheric Phase Fluctuations Observed by Three-Element VLBI.

Author

Nishio, Masanori, Qinghui Liu, Miyazaki, Tomoyuki, Hirata, Masako, Kuroki, Yoshinobu, Kusuhata, Masahiko, Iwashita, Naoki, Minamitake, Chikara, Yasuda, Shigeru, Iino, Naoko, Omodaka, Toshihiro, Kameya, Osamu, Kawano, Nobuyuki, Suzuyama, Tomonari, Shibuya, Yasuhisa, and Kurihara, Noriyuki

Subjects

GEOSTATIONARY satellites, VERY long baseline interferometry, STANDARD deviations, STABILITY (Mechanics), INTERFEROMETRY

Abstract

The beacon signals from a geostationary satellite were observed using three-element very long baseline interferometry (VLBI), and the phase fluctuations along the baselines between three sites were obtained. The atmospheric phase fluctuations at each observation site were derived from the baseline phase fluctuation data. The fluctuations were classified into three time-interval regions based on the dependence of the Allan standard deviation of the fluctuations on the time interval. In the region where the interval was less than a few seconds and in the one where it was greater than one hundred seconds, the curve of the Allan standard deviation was steep and showed the property of white phase noise. In the region between these two regions, the dependence of the Allan standard deviation on the time interval was weak. The magnitude of the Allan standard deviations for the three observation sites showed time variations in the region where the time interval was longer than a few seconds. Comparison with the weather conditions suggested that the time variations of the Allan standard deviation reflected atmospheric instability above the sites. [ABSTRACT FROM AUTHOR]

Published

2007

12. Optical timing distribution system with femtosecond stability.

Author

Amemiya, Masaki, Watabe, Ken-ichi, Suzuyama, Tomonari, Naito, Takashi, and Tsuchida, Hidemi

Abstract

Stable timing distribution is a key technology for the many fields that use timing signals for synchronization. The frequency of the timing signal depends on the field and multiple timing signals are sometimes required. In our DWDM-based timing distribution system, phase deviation is detected by high-speed round-trip signal (10 GHz signal is used as this control signal). Fiber stretchers are controlled so as to minimize the phase deviation of the control signal. Multiple signals and the control signal are densely multiplexed and transmitted through the same stretchers. Therefore, the transmission of all signals is stabilized. This configuration provides a flexible platform for distributing various RF or microwave signals. As an example of arbitrary timing signals, a 1 GHz signal is transmitted over a length-stabilized 400-m fiber for more than 1 day. The recorded propagation time fluctuations are 10.4 and 2.8 fs rms for the 1 and 10 GHz signals, respectively. The Allan deviations are 2.7 × 10−19 (1 GHz) and 6.0 × 10−20 (10 GHz) for the averaging time of 105 s. © 2012 Institute of Electrical Engineers of Japan. Published by John Wiley & Sons, Inc. [ABSTRACT FROM AUTHOR]

Published

2012

13. Precision measurement with optical frequency combs and clocks.

Author

Hong, Feng-Lei, Inaba, Hajime, Iwakuni, Kana, Nakajima, Yoshiaki, Hosaka, Kazumoto, Yasuda, Masami, Kohno, Takuya, Akamatsu, Daisuke, Tanabe, Takehiko, Okubo, Sho, Suzuyama, Tomonari, Amemiya, Masaki, and Onae, Atsushi

Published

2013

14. Improved absolute frequency measurement of the 171Yb optical lattice clock towards the redefinition of the second.

Author

Yasuda, Masami, Inaba, Hajime, Kohno, Takuya, Tanabe, Takehiko, Nakajima, Yoshiaki, Hosaka, Kazumoto, Akamatsu, Daisuke, Onae, Atsushi, Suzuyama, Tomonari, Amemiya, Masaki, and Hong, Feng-Lei

Published

2013

15. Spectroscopy and frequency measurement of the 87Sr clock transition by laser linewidth transfer using an optical frequency comb.

Author

Akamatsu, Daisuke, Inaba, Hajime, Hosaka, Kazumoto, Yasuda, Masami, Onae, Atsushi, Suzuyama, Tomonari, Amemiya, Masaki, and Hong, Feng-Lei

Abstract

We performed spectroscopic observations of the 698-nm clock transition in 87Sr confined in an optical lattice using a laser linewidth transfer technique. A narrow-linewidth laser interrogating the clock transition was prepared by transferring the linewidth of a master laser (1064 nm) to that of a slave laser (698 nm) with a high-speed controllable fiber-based frequency comb. The Fourier-limited spectrum was then observed for an 80-ms interrogating pulse. We determined that the absolute frequency of the 5s21S0–5s5p 3P0 clock transition in 87Sr is 429 228 004 229 872.0 (1.6) Hz referenced to the SI second. [ABSTRACT FROM AUTHOR]

Published

2014

16. Improved Absolute Frequency Measurement of the 171Yb Optical Lattice Clock towards a Candidate for the Redefinition of the Second.

Author

Yasuda, Masami, Inaba, Hajime, Kohno, Takuya, Tanabe, Takehiko, Nakajima, Yoshiaki, Hosaka, Kazumoto, Akamatsu, Daisuke, Onae, Atsushi, Suzuyama, Tomonari, Amemiya, Masaki, and Hong, Feng-Lei

Abstract

We demonstrate an improved absolute frequency measurement of the 1S0–3P0 clock transition at 578 nm in 171Yb atoms in a one-dimensional optical lattice. The clock laser linewidth is reduced to ≈2 Hz by phase-locking the laser to an ultrastable neodymium-doped yttrium aluminum garnet (Nd:YAG) laser at 1064 nm through an optical frequency comb with an intracavity electrooptic modulator to achieve a high servo bandwidth. The absolute frequency is determined as 518 295 836 590 863.1(2.0) Hz relative to the SI second, and will be reported to the International Committee for Weights and Measures. [ABSTRACT FROM AUTHOR]

Published

2012