Abstract: A food grinder (10) makes a sound or vibrates with a frequency that changes between a first mode when the grinding mechanism (22, 24, 36) is performing a grinding operation while there is bulk food ingredient within the grinding chamber, and a second mode when the grinding mechanism (22, 24, 36) is performing a grinding operation while there is no bulk food ingredient within the grinding chamber, has a detector (44) for sensing the change in frequency and a controller (42) responsive to the detector (44) for controlling the application of electrical power to the grinding mechanism (22, 24 36). Power is first applied when a start grind switch is manually actuated and is later automatically removed in response to a timer (54) a preselected time period after the detector senses that the grinding chamber is empty of bulk food ingredient to be ground.

Abstract: A beverage dispenser (10) having a hollow, insulated dispenser body (12), a removable cover (16) with an inlet opening (24) for receipt of freshly brewed beverage to an interior of the dispenser body (12), a closed bottom (18) and a faucet (22) for dispensing beverage from the body (12) has a level display system including an elongate, relatively flexible, probe body, or down tube (40) with a flexible probe circuit and having a bottom and a top with a plurality of electrically conductive sensors (43, 45, 47 and 49) mounted within an elongate mounting groove (182, FIGS. 21-23) formed in, and extending along, the elongate relatively rigid probe body (36). The flexible probe assembly (40) is secured within the groove by non-adhesive means, either by a thermal fusion joint 183) formed during injection molding (FIG. 20) of the rigid probe body (36) or by mechanical tabs (178, 180).

Abstract: A beverage dispenser (20) has a double-walled tubular, preferably cylindrical, sensor (22) that is immersed in liquid (23), such as coffee or tea, within an opaque, stainless steel container, or beverage dispenser (25) has a double-walled tubular sensor connected via two conductive paths (24, 26) to two inputs (28, 30), respectively, of a resistance measuring circuit (32) that measures the resistance between the two inputs (28, 30) to produce an electrical, direct current, resistance output signal that varies with changes in the instantaneous resistance between the two inputs (28, 30) The resistance output signal is connected to an input (34) of an electronic controller (40) The electronic controller (40) calculates the depth of the liquid (23) based on the magnitude of the resistance output signal applied to the input (34).

Abstract: A beverage dispenser (10) with a beverage quantity indicating display (30) controlled by a microprocessor (66) in response to variations in capacitance of a plurality of sensing capacitors (72) detected by a capacitive sensing circuit (70) including one of a general purpose input/output integrated capacitive touch-key sensor, and a general purpose, integrated, input/output port expander with an integrated capacitive touch-key for reduced power consumption, sensitivity and reliability. A reference capacitor (C8) is located above the maximum height (52) of the beverage (74) to keep it spaced from the beverage (74) in air is used to compensate for changes in capacitance of the sensing capacitors (72) due to variations in temperature. All the capacitors (72, C8) are formed from pairs of planer conductive plates (54, 56) respectively mounted to opposed parallel interior surfaces (58, 60) of a sensing tube (36) attached to a down tube (34).

Abstract: A beverage dispenser (20) has a double-walled tubular, preferably cylindrical, sensor (22) that is immersed in liquid (23), such as coffee or tea, within an opaque, stainless steel container, or beverage dispenser (25) has a double-walled tubular sensor connected via two conductive paths (24, 26) to two inputs (28, 30), respectively, of a resistance measuring circuit (32) that measures the resistance between the two inputs (28, 30) to produce an electrical, direct current, resistance output signal that varies with changes in the instantaneous resistance between the two inputs (28, 30) The resistance output signal is connected to an input (34) of an electronic controller (40) The electronic controller (40) calculates the depth of the liquid (23) based on the magnitude of the resistance output signal applied to the input (34).

Abstract: A method of communicating an optical signal includes generating an optical signal at a bit rate of at least 2.5 Gb/s. The optical signal including at least thirty optical channels. In one particular embodiment, at least some of the thirty optical channels reside within a 1567-1620 nanometer wavelength range. The method also includes receiving the optical signal at a ROPA that includes a rare-earth doped optical fiber. In addition, the method includes introducing a pump signal to a communication span of the unrepeatered optical communication system. The pump signal operable to amplify the optical signal by Raman amplification within the communication span and including at least one pump signal wavelength operable to excite the rare-earth doped fiber. The method further includes receiving the optical signal after the optical signal has traversed at least 200 kilometers of the communication span.

Abstract: An optical communication system includes a transmission fiber that is operable to receive at least one optical signal and at least one pump signal. The optical signal includes one or more optical signal wavelengths and a power level at approximately a minimum threshold power level. The pump signal co-propagates with at least a portion of the optical signal over at least a portion of the transmission fiber. In one particular embodiment, the pump signal operates to amplify the optical signal to approximately a maximum threshold power level as the pump signal and the optical signal traverse the portion of the transmission fiber.

Abstract: An optical communication system includes a plurality of optical add/drop multiplexers (OADMs). The plurality of OADMs includes at least five low distortion OADMs. Each OADM is coupled between spans of a multiple span communication link and operable to receive a multiple wavelength signal. The multiple wavelength signal includes a plurality of bands of wavelength signals each separated from other bands of wavelength signals by one or more guard-channels. In one embodiment, each of the at least five low distortion OADMs adds/drops a common first band of wavelengths to/from the multiple wavelength signal. In some embodiments, a spectral distortion associated with a pass-through wavelength signal spectrally adjacent to one of the one or more guard-channels is no more than three decibels after exiting the last of the plurality of low distortion OADMs. In those embodiments, the guard-channel is adjacent to the first band of wavelengths.

Abstract: An optical communication system includes a gain medium that is capable of receiving at least one optical signal that includes one or more optical signal wavelengths. The system also includes one or more pump sources that are capable of generating at least one pump signal for introduction to the gain medium. The pump signal includes one or more fractional Raman order pump wavelengths having a Raman gain peak that is a non-integer multiple of one stokes shift from each of the one or more optical signal wavelengths. In one particular embodiment, the pump signal interacts with the optical signal as the pump signal traverses at least a portion of the gain medium.

Abstract: An optical communication system includes a plurality of optical add/drop multiplexers (OADMs). The plurality of OADMs includes at least five low distortion OADMs. Each OADM is coupled between spans of a multiple span communication link and operable to receive a multiple wavelength signal. The multiple wavelength signal includes a plurality of bands of wavelength signals each separated from other bands of wavelength signals by one or more guard-channels. In one embodiment, each of the at least five low distortion OADMs adds/drops a common first band of wavelengths to/from the multiple wavelength signal. In some embodiments, a spectral distortion associated with a pass-through wavelength signal spectrally adjacent to one of the one or more guard-channels is no more than three decibels after exiting the last of the plurality of low distortion OADMs. In those embodiments, the guard-channel is adjacent to the first band of wavelengths.

Abstract: In one embodiment, an optical amplifier includes a gain medium operable to receive a plurality of signals each having a center wavelength and a noise figure associated with at least a portion of the amplifier and varying as a function of wavelength. At least two of the plurality of signals have launch powers that are a function of a magnitude of the noise figure measured at or near the center wavelength of that signal.

Abstract: Method for production of new, thermal and chemical resistant polyurethane plastics, particularly in the form of foams, these foams being obtained from the reaction of di- or poly- isocyanates with polyols, said polyols having the formula 1 or 2 as herein described, Ar in the said formulas representing a benzene, naphthalene or anthracene ring, which may be singly or multiply substituted with a halogen atom, alkyl radical, aryl radical or allyl radical, Z representing the oxygen atom, a group SO.sub.2 or a divalent radical --CRR.sub.1 -- where R and R.sub.1 represent a hydrogen atom or an alkyl radical, m and r represent 0 or 1, and n and p represent an integer 1-10, or their mixtures with other low-viscosity polyols or with a compound having formula 3 as herein described in which R.sub.2 represents a simple or branched alkyl or aryl radical which can be substituted by a lower alkyl or aryl radical or by halogen atoms added in a quantity of 0.