The present invention discloses imaging antenna and array by designing the system in the Ultra-high frequency (UHF) band 300 MHz-3 GHz with resolution comparable to high-frequency microwave imagers (i.e., super-resolution). To obtain high resolution at relatively low system cost and complexity, a novel modulated antenna array element design is disclosed. The antenna is basically small loop loaded with spiral resonator. The selection of the SR as a resonator provides for adequate miniaturization rate at the lower end of the microwave frequency range. A non-modulated version of this antenna has been conceived and yielded a resolution comparable to the 24 GHz antennas while operating at 426 MHz. The disclosed antenna element operating at 426 MHz produced images with very comparable attributes to the one obtained at 24 GHz. In fact, it has been established that proposed antenna element yield a resolution of around 5 mm (much less that the wavelength divided by 100), and hence it provides super-resolution as long as the diffraction limit is concerned. The present invention further discloses an imaging probe unit comprising a imaging sensor loaded with a PIN diode, an L-matching circuit and an LC resonant detuning circuit. The present invention further discloses a one-dimensional array, comprising a plurality of imaging probe units which are placed side by side in very close proximity of each other.

An acquisition section (12) acquires a reflected wave intensity image in which a reflected wave intensity of an electromagnetic wave that has been radiated in a direction through a surface of a reinforced concrete structure toward an interior of the reinforced concrete structure at respective positions on the surface of the reinforced concrete structure is expressed by pixel values of pixels corresponding to each of the respective positions. A setting section (14) sets an evaluation target range in the acquired reflected wave intensity image. A computation section (16) computes a statistical indicator of a type set according to the set range for pixel values in the reflected wave intensity image. An evaluation section (18) evaluates a degree of deterioration of the reinforced concrete structure using the computed values.

A looseness detection structure includes: a structure (transducer) T which is formed on a surface of a cable; a screw which tightens and fixes the cable in contact with the structure T; and a terminal (detection unit) which transmits a transmission signal to the structure T, receives a reception signal returning after propagating through the structure T, and detects the loosening of the screw based on a change in the reception signal.

An optical characteristics measuring device includes a first light source capable of irradiating a sample with light and a second light source capable of irradiating the sample with microwaves. A measuring device measures microwave power of the reflection of the microwaves from the sample. A calculation unit calculates a parameter relating to the electrical conductivity of the sample using the microwave power of the reflected waves measured by the measuring device. A control unit controls the intensity of the light of the first light source so that the parameter becomes approximately a predetermined value. The calculation unit specifies first to n-th intensities of the light at which the parameter becomes approximately the predetermined value for each of the first to n-th wavelengths of the light and obtains relationships between the first to n-th wavelengths and the first to n-th intensities corresponding to the respective first to n-th wavelengths.

An optical characteristics measuring device includes a first light source capable of irradiating a sample with light and a second light source capable of irradiating the sample with microwaves. A measuring device measures microwave power of the reflection of the microwaves from the sample. A calculation unit calculates a parameter relating to the electrical conductivity of the sample using the microwave power of the reflected waves measured by the measuring device. A control unit controls the intensity of the light of the first light source so that the parameter becomes approximately a predetermined value. The calculation unit specifies first to n-th intensities of the light at which the parameter becomes approximately the predetermined value for each of the first to n-th wavelengths of the light and obtains relationships between the first to n-th wavelengths and the first to n-th intensities corresponding to the respective first to n-th wavelengths.

Testing systems and methods are provided for a smoking article to determine a characteristic of the smoking article, such as density of a material used therewith. The testing system may include a test fixture and an electromagnetic energy generating device The testing methods may be carried out by subjecting the material to the electromagnetic energy and determining the amount of energy absorbed by the material.

Testing systems and methods are provided for a smoking article to determine a characteristic of the smoking article, such as density of a material used therewith. The testing system may include a test fixture and an electromagnetic energy generating device The testing methods may be carried out by subjecting the material to the electromagnetic energy and determining the amount of energy absorbed by the material.

A method of measuring properties of a moving cellulose, paper or board sheet. A first parameter of a first resonance caused by the moving sheet in a frequency range 1 GHz to 25 GHz of electromagnetic radiation is measured. A second parameter of an electromagnetic signal transmitted between at least a pair of transceiver parts of a transceiver sensor located on opposite sides of the moving sheet through the moving sheet is measured in a frequency range 25 GHz to 1000 GHz. A minimum difference between the frequency ranges related to the first parameter and the second parameter being at least 5 GHz. Both the dry stuff content and the weight of water per unit of area are determined on the basis of the first parameter, the second parameter and available information related to a distance travelled by the electromagnetic signal.

A multi-arm robot used for tunnel lining inspection and defect diagnosis in an operation period, including a moving platform, where an environment detection device and a defect infection device are disposed on the moving platform, the defect infection device is disposed on the moving platform by using a multi-degree-of-freedom mechanical arm, and an attitude detection module is disposed on each multi-degree-of-freedom mechanical arm; a controller receives environmental data and mechanical arm attitude data sensed by the environment detection device and the attitude detection module, and sends a control instruction to the moving platform and the multi-degree-of-freedom mechanical arm according to the environmental data, to implement movement of the robot; and the controller receives tunnel lining structural data sensed by the defect infection device, and performs defect diagnosis. Overall automatic inspection can be implemented both on the surface and inside of the tunnel lining.

A multi-arm robot used for tunnel lining inspection and defect diagnosis in an operation period, including a moving platform, where an environment detection device and a defect infection device are disposed on the moving platform, the defect infection device is disposed on the moving platform by using a multi-degree-of-freedom mechanical arm, and an attitude detection module is disposed on each multi-degree-of-freedom mechanical arm; a controller receives environmental data and mechanical arm attitude data sensed by the environment detection device and the attitude detection module, and sends a control instruction to the moving platform and the multi-degree-of-freedom mechanical arm according to the environmental data, to implement movement of the robot; and the controller receives tunnel lining structural data sensed by the defect infection device, and performs defect diagnosis. Overall automatic inspection can be implemented both on the surface and inside of the tunnel lining.