33 results about "Incorrect Measurement" patented technology

The invention relates to the field of detection techniques for body temperatures, and particularly relates to a system and a method for detecting a body temperature. The system for detecting the body temperature comprises an intelligent terminal, a CPU (central processing unit) module, a shooting module and a body temperature detecting module, wherein the CPU module, the shooting module and the body temperature detecting module are arranged in the intelligent terminal respectively; the CPU module is used for controlling the on and off of the body temperature detecting function of the body temperature detecting module; the shooting module is used for aiming at a to-be-detected object; the body temperature detecting module is used for detecting the surface temperature of a human body of the to-be-detected object and displaying the detected surface temperature of the human body in a shooting preview interface of the shooting module. The system and the method for detecting the body temperature are simple to operate, a measurement of the body temperature can be completed so long as a mobile phone is at hand, a thermometer is not needed to be sought everywhere, the problem of an inaccurate measurement caused by an incorrect measurement technique does not need to be worried, so that the temperature measurement is convenient and quick, and further, the carrying is convenient.

What is disclosed is a device (1) for automatic detection of a possible incorrect measurement, wherein the device (1) comprises at least one reflected light illumination apparatus (14) and/or a transmitted light illumination apparatus (6) and at least one imaging optical system (9) and one detector (11) of a camera (10) for imaging structures (3) on a substrate (2), wherein a first program portion (17) is linked to the detector (11) of the camera (10), said detector being provided for determining the position and/or dimension of the structure (3) on the substrate (2), wherein the device (1) determines and records a plurality of measurement variables M_j, j ε {1, . . . , L}, from which at least one variable G can be determined, wherein a second program portion (18) is linked to the detector (11) of the camera (10), said program portion calculating an analysis of the measurement variables M_j with regard to a possible incorrect measurement. Also disclosed is a method for automatic detection of a possible incorrect measurement wherein an analysis of the measurement variables M_j with regard to a possible incorrect measurement is calculated with a second program portion (18) which is linked to the detector (11) of the camera (10).

The present invention relates to a detection system for improving accuracy of hematocrit measurement and an operation control method. The detection system for hematocrit measurement comprises a central processing unit, an excitation source unit, a blood sample unit, a precise measurement circuit unit and a signal collecting unit. The present invention has the beneficial effects that the HCT measurement precision is improved by generating a sine wave by the excitation source unit and performing control by the central processing unit; the detection system of the present invention is simple and reliable, and implements precise measurement; and the measurement precision in the present invention is far greater than that of a conventional measurement technology and can be within 0.2%. Furthermore, due to a self-detection function, the measurement is quite reliable without the risk of resulting incorrect measurement data from a circuit failure.

A technology is provided that makes it possible for even a beginner to determine whether a measurement result is correct, to thereby prevent the use of incorrect measurement data, and to improve the reliability of an analysis result. In a three-dimensional shape measurement apparatus 100 that measures a three-dimensional shape of a specimen 3 in a non-contacting manner, a score that evaluates the reliability of measurement data is calculated for each measurement point by use of information obtained during a process of estimating the height of the specimen 3 or the estimated height. Measurement data is processed according to a result of evaluating the measurement data for each measurement point by use of the score.

The invention provides a method for measuring the temperature of a reaction chamber of a vapor deposition device. The temperature of the reaction chamber is measured by arranging temperature detecting units inside and outside the reaction chamber respectively in the prior art, which has the problems of cost waste, incorrect measurement and hidden danger. The invention provides a temperature measuring method which includes that: an inner temperature detecting unit and an outer temperature detecting unit are respectively arranged inside and outside the reaction chamber of the vapor deposition device; then the temperature of the vapor deposition device is changed to cover the permitted temperature range of the vapor deposition device; then the temperature detected by the inner and outer temperature detecting units is read and the temperature deviation value of the inner temperature and the outer temperature is calculated; then the inner temperature detecting unit is dismounted, vapor deposition is carried out again by the vapor deposition device, and then the temperature detected by the outer temperature detecting unit is read; finally, the temperature of the reaction chamber of the vapor deposition device is calculated according to the temperature deviation value and the temperature detected by the outer temperature detecting unit. The method of the invention can measure the temperature of the reaction chamber safely and accurately with low cost.

A properly calibrated load-cell is critical for the safe operation of a rod-pumping system. Load readings are utilized for shutdown thresholds, and incorrect measurements can cause those safe load limits to be exceeded. Correct surface load, combined with position measurement, is also important for the diagnosis of the complete pumping system. The diagnostic method for calculating down-hole conditions presents an interesting opportunity to validate surface load measurements, even from the incorrect load measurements themselves. The calculated down-hole dynamometer card will be transposed on a distinct diagonal with respect to both load and position, if the input surface load measurements are incorrect. A load offset can then be identified from this shifting and the surface load measurements can be corrected. Calculated pump cards have been traditionally aligned with the surface dyno card position, and so this diagonal pump card shifting correlation with incorrect, or unexpected, surface load has not been realized.

The present invention provides a method and system of measuring knowledge point relationship strength, the method comprising calculating explicit relationship strength for all knowledge points and generating a knowledge point relationship strength matrix M; constructing a weighted and directed graph G according to the knowledge point relationship strength matrix of all knowledge points; calculating knowledge point implicit relationship strength values according to the weighted and directed graph and generating a knowledge point implicit relationship strength matrix I; traversing the knowledge point implicit relationship strength matrix I and updating the knowledge point relationship strength matrix M. The above technical solution may effectively avoid the problem of lack of an absolute measurable value for the determination of relationship strength, incorrect measurement of relationship strength, or unable to discover some stronger relationship strength in the prior art.

Disclosed is a precise step counting method using human body capacitance, relating to the field of electronic communications, and in particular to a method for implementing precise step counting using human body capacitance. At present, a wearable intelligent device having a step counting function measures a number of steps by means of an inertial sensor, but has limited precision in a measurement result. Due to the complexity of motion of a human body, missed measurement and incorrect measurement often occur in the inertial sensor-based measurement of the number of steps. The recognition and calculation of the number of steps also occupy a large number of hardware resources. In this respect, a precise step counting method based on human body capacitance, a human body's electrostatic field, or a human body surface potential is provided. When a human body is walking, the actions of leg lifting and leg lowering would change human body capacitance, and the number of steps can be conveniently and quickly measured by detecting a change in a physical signal caused by a change in the human body capacitance, such as a change in a voltage signal of human body skin and a change in a frequency. The method implements precise step counting without occupying hardware spaces and resources, has the advantage of low power consumption, and can be embedded into all current wearable intelligent devices that require a step counting function).

While determining a leak resistance (Ra, Rb) of a subscriber connection line (TAL) provided, for example, with two wires (a, b) in a communications network, a capacitor (C) connected between said two wires is discharged prior to measuring leakage currents (IRa1, IRa2). For this purpose, prior to be connected to a high resistance of the other wire (b), the measurable wire (a) and the other mentioned wire (b) are supplied with a constantly falling and increasing voltage (UaG, UbG). For that, the final value of said tensions (UaG, UbG) is determined in such a way that, when the connection to the high resistance of the other wire (b) is produced, the voltage of said wire (b) is equal to 0 volt. The leakage current is measured only when the discharge process is over, thereby making it possible to avoid an incorrect measurement caused by a current coming from the capacitor (C).

Before technical components are further processed, they are checked for the functionality thereof. In this case, an incorrect judgment of the functionality can occur due to measurement errors or incorrect measurements, which in turn results in a very inefficient test. The invention provides a method and a device by which an increased measurement accuracy can be achieved. This is achieved in that at least one first electrical voltage value is measured at a first constant measurement current and at least one second electrical voltage value is measured at a second constant measurement current at terminals of the component. Every measured voltage value is scaled respectively using a profile factor PF to form a measured value M, and only measured values M that are located at least with a tolerance range in a common value range are used for the determination of an electrical parameter.