Abstract: A tractor includes a working motor, a work machine including a roller configured to rotate by an output from the working motor, a support mechanism configured to support the work machine such that a working posture and a retracting posture are achievable, and a control device. The control device executes: an adherence amount acquisition process of acquiring an estimated adherence amount as an estimated value for the amount of mud attached to the roller; and a mud removal process of, when the estimated adherence amount is equal to or more than a determination adherence amount, removing the mud from the roller by driving the working motor in a state where the work machine takes the retracting posture.

Abstract: A liquid humic acid extract that does not form precipitates when combined with a liquid fertilizer containing at least one of Mg, Fe, Zn and Mo and having an electric conductivity of 90 ms/cm or more. A liquid humic acid extract containing humic acid that has a mass-average molecular weight of 100 to 1,200, and having a total organic carbon concentration of 15,000 to 25,000 mg/L and a pH of 0.5 to 4.0. Preferably, the liquid humic acid extract contains a humic acid having a mass-average molecular weight of 100 to 1,200, and has a total organic carbon concentration of 15,000 to 25,000 mg/L and a pH of 0.5 to 4.0. A liquid humic acid extract that hardly forms precipitates and realizes an increase in the crop yield.

Abstract: A Nordic walking pole has a transmission device attached thereto and a switch thereof is pushed to transmit a signal indicating the start or end of Nordic walking. A pedometer receives the signal from the transmission device to thereby detect that the start or end of Nordic walking is instructed (S107). Assuming that the Nordic mode is specified when the current walking mode is a normal walking mode, the parameter for Nordic walking is set as a parameter for the arithmetic operation (S111). Assuming that the normal walking mode is specified when the current walking mode is a Nordic mode, the parameter for the normal walking mode is set as a parameter for the arithmetic operation (S113).

Abstract: A pedometer can be equipped with a sensor unit including a sensor for detecting motion by detecting acceleration of a displacement of a main body. Detected acceleration can be compared with a threshold value to determine whether the acceleration corresponds to body motion or to a setting operation. Various setting operations can be performed based on shaking of the pedometer.

Abstract: The present invention provides an electronic thermometer which is easily installed at an appropriate position, and is excellent in the measurement accuracy. In the electronic thermometer provided with an internally hollow casing 10 having an opening portion at the tip, a temperature sensor 21 connected by lead wire 22 drawn out from the inside of the casing 10 to the outside of the casing through the opening portion, and a cap 30 closing the opening portion, there is provided a positioning unit positioning the temperature sensor 21 at the tip of the casing 10.

Abstract: A Nordic walking pole has a transmission device attached thereto and a switch thereof is pushed to transmit a signal indicating the start or end of Nordic walking. A pedometer receives the signal from the transmission device to thereby detect that the start or end of Nordic walking is instructed (S107). Assuming that the Nordic mode is specified when the current walking mode is a normal walking mode, the parameter for Nordic walking is set as a parameter for the arithmetic operation (S111). Assuming that the normal walking mode is specified when the current walking mode is a Nordic mode, the parameter for the normal walking mode is set as a parameter for the arithmetic operation (S113).

Abstract: A first thermistor 8 and a second thermistor 9 are arranged forwardly and rearwardly of a thermopile sensor 5. A thermopile chip 55 is arranged and interposed between the first thermistor 8 and an integrated thermistor 57. A sensor cover is mounted in contact with front and side portions of a can portion 59 of a thermopile casing 56. A temperature or a radiant quantity of infrared rays on the front portion of the can portion is estimated from a temperature change of the integrated thermistor per second.

Abstract: A first thermistor 8 and a second thermistor 9 are arranged forwardly and rearwardly of a thermopile sensor 5. A thermopile chip 55 is arranged and interposed between the first thermistor 8 and an integrated thermistor 57. A sensor cover is mounted in contact with front and side portions of a can portion 59 of a thermopile casing 56. A temperature or a radiant quantity of infrared rays on the front portion of the can portion is estimated from a temperature change of the integrated thermistor per second.

Abstract: Temperature states of a clinical thermometer body and an environment are estimated by temperatures measured by a first temperature sensor integrally formed together with an infrared sensor arranged to the distal end of a probe and a second temperature sensor arranged on the bottom side of a probe holder, and processes suitable for the respective temperature states are performed. An estimation error or the reliability of an estimation value is calculated by the temperatures to notify a user of the estimation error or the reliability by an LCD or the like.

Abstract: The invention relates to a fluorescence measuring apparatus to which a CCD camera capable of measuring fluorescent components emitted from a specimen corresponding to excitation pulse components emitted at regular intervals toward the specimen is applied. The fluorescence measuring apparatus has at least a CCD and a controller. The CCD includes photoelectric converters for implementing photoelectric conversion of the fluorescent components emitted from the specimen, and charge storage elements for storing and transferring charges resulting from the photoelectric conversion by the photoelectric converters. The controller outputs an electronic shutter signal for sweeping away the charge resulting from the photoelectric conversion by each photoelectric converter, a readout signal for reading the charge resulting from the photoelectric conversion, to the charge storage element, and a transfer signal for sequentially transferring the charge thus read.

Abstract: A first thermistor 8 and a second thermistor 9 are arranged forwardly and rearwardly of a thermopile sensor 5. A thermopile chip 55 is arranged and interposed between the first thermistor 8 and an integrated thermistor 57. A sensor cover is mounted in contact with front and side portions of a can portion 59 of a thermopile casing 56. A temperature or a radiant quantity of infrared rays on the front portion of the can portion is estimated from a temperature change of the integrated thermistor per second.

Abstract: In turn-on state, it is monitored whether a power switch 15 is pressed or not (ST1). When not pressed, it is continuously monitored whether pressed or not. When it is judged that the power switch 15 is pressed, it is monitored whether the power switch 15 is pressed continuously for no less than 2 seconds or not (ST2). When it is judged that the power switch 15 is not pressed continuously for no less than 2 seconds, back to ST1, it is continuously monitored whether the power switch 15 is pressed or not. When it is judged that the power switch 15 is pressed continuously for no less than 2 seconds, the process of turning off the power is started (ST3).

Abstract: Temperature states of a clinical thermometer body and an environment are estimated by temperatures measured by a first temperature sensor integrally formed together with an infrared sensor arranged to the distal end of a probe and a second temperature sensor arranged on the bottom side of a probe holder, and processes suitable for the respective temperature states are performed. An estimation error or the reliability of an estimation value is calculated by the temperatures to notify a user of the estimation error or the reliability by an LCD or the like.

Abstract: This invention is designed such that measurement can be performed only when a probe is sufficiently inserted into an external ear canal. A decision whether the probe is sufficiently inserted into the external ear canal or not is performed on the basis of a detected temperature.

Abstract: A first thermistor 8 and a second thermistor 9 are arranged forwardly and rearwardly of a thermopile sensor 5. A thermopile chip 55 is arranged and interposed between the first thermistor 8 and an integrated thermistor 57. A sensor cover is mounted in contact with front and side portions of a can portion 59 of a thermopile casing 56. A temperature or a radiant quantity of infrared rays on the front portion of the can portion is estimated from a temperature change of the integrated thermistor per second.

Abstract: Temperature states of a clinical thermometer body and an environment are estimated by temperatures measured by a first temperature sensor integrally formed together with an infrared sensor arranged to the distal end of a probe and a second temperature sensor arranged on the bottom side of a probe holder, and processes suitable for the respective temperature states are performed. An estimation error or the reliability of an estimation value is calculated by the temperatures to notify a user of the estimation error or the reliability by an LCD or the like.

Abstract: A first thermistor 8 and a second thermistor 9 are arranged forwardly and rearwardly of a thermopile sensor 5. A thermopile chip 55 is arranged and interposed between the first thermistor 8 and an integrated thermistor 57. A sensor cover is mounted in contact with front and side portions of a can portion 59 of a thermopile casing 56. A temperature or a radiant quantity of infrared rays on the front portion of the can portion is estimated from a temperature change of the integrated thermistor per second.

Abstract: A first thermistor 8 and a second thermistor 9 are arranged forwardly and rearwardly of a thermopile sensor 5. A thermopile chip 55 is arranged and interposed between the first thermistor 8 and an integrated thermistor 57. A sensor cover is mounted in contact with front and side portions of a can portion 59 of a thermopile casing 56. A temperature or a radiant quantity of infrared rays on the front portion of the can portion is estimated from a temperature change of the integrated thermistor per second.