Thermal image evaluation of crop diseases in the incubation period.

Background: Early blight is one of the main diseases that causes serious pepper yield and quality reduction. The identification of the presymptomatic features during the incubation period is of great research significance, in that scientific prevention measures in the incubation period may effectively reduce the loss of peppers.

Results: The present study confirms the feasibility of the identification of presymptomatic features in pepper early blight by infrared thermography during the incubation period.

Broadband negative-refractive index terahertz metamaterial with optically tunable equivalent-energy level.

An optically tunable terahertz negative-refractive index metamaterial (NIM) is proposed. The NIMs are composed of two aluminum rings and two photosensitive ring-shaped silicon apertures coaxially coated on the both sides of Teflon substrate. The NIMS are also designed to realize wide incident angle, polarization insensitivity, and tunability.

First-order nonparaxial scalar theory of surface and bulk scattering for high-quality optical coatings.

A novel nonparaxial scalar theory is presented to calculate the angular scattering that is due to interface roughnesses or bulk inhomogeneities in a high-quality optical coating. Based on the empirically modified Beckmann-Kirchhoff surface scatter model, this theory in surface scattering and bulk scattering predicts similar formulas for the angular scattered intensity, and at the same time provides new understanding and insight into multilayer scattering phenomena. It is worth noting that the derived expressions are in the same form as those given by the typical vector methods.

A broadband tunable terahertz negative refractive index metamaterial.

A strategy to greatly broaden negative refractive index (NRI) band, reduce loss and ease bi-anisotropy of NRI metamaterials (MMs) has been proposed at terahertz frequencies. Due to the symmetric structure of the MM, the transmission and refractive index are independent to polarizations of incident radiations, and a broadband NRI is obtainable for the range of the incident angle from 0° to 26°. In addition, THz MMs' properties such as transmission, phase and negative refraction exhibit a real-time response by controlling the temperature.

A simple digital control system with field-programmable gate array for stabilization of CO laser output.

A simple digital control system was designed to stabilize CO laser based on digital signal processing with the Field-Programmable Gate Array (FPGA) controlling chip and Very-High-Speed Integrated Circuit Hardware Description Language program. In this system, the control parameters were easily determined by software real-time control, and the control circuit was also designed compactly. In addition, the theoretical analysis on the stabilization of CO laser output characteristics was presented based on the photoacoustic effect, and the corresponding experiments on the stabilization of CO laser output characteristics were further performed.

[Study on Output Frequency Stability for Optically Pumped THz Lasers].

The frequency stability of the terahertz (THz) radiation source is one of the key issues which directly affect its application regarding to THz imaging, Radar detection, Coherent communication and so on. Based on two-photon light shift effect, the physical model for the frequency shift of optically pumped THz lasers has been built up and the analytical formula for calculating the frequency shift has been derived. Taking the optically pumped methanol(CH3OH) for example, the absorption line of methanol under different pressure has been given, the influence of the bump laser frequency offset and the power of pump laser on the frequency stability of output THz laser have been analyzed quantitatively while the effect of the pressure in THz cavity on the THz laser frequency drift has also been discussed.