Abstract: A footwear includes a footwear upper attached to a sole. The footwear upper includes at least one leather base layer having a base layer top grain surface, and at least one leather attachment layer having a top grain surface and a flesh-side surface. The leather base layer is glued to the leather attachment layer with the base layer top grain surface facing the flesh-side of the leather attachment layer.

Abstract: A method of manufacturing a footwear includes the steps of providing a leather base layer and providing a leather attachment layer. The leather base layer and the leather attachment layer are fixed against each other with an intermediate application of adhesive between them. The applied adhesive is activated. The leather base layer and the leather attachment layer are forced against each other under a pressure with the adhesive between them. The adhesive is cured and thereby the leather base layer and the leather attachment layer are bonded to each other. The bonded leather base layer and the leather attachment layer are integrated as part of the footwear.

Abstract: A frequency divider includes a set of frequency-dividing units coupled in series in a sequential order, with the sequence of frequency-dividing units including a lowest unit and a highest unit, with the remaining units being disposed in series between the lowest unit and the highest unit. The lowest unit is coupled to receive an input clock whose frequency is to be divided and provided as an output clock. Each frequency-dividing unit in the set is coupled to receive a corresponding first clock as an input and is operable to generate a corresponding second clock as an output. The frequency divider includes a logic block to generate a first set of edges of the output clock synchronous with the input clock. The logic block is designed to generate a second set of edges of the output clock synchronous with the output clock of a highest operative frequency-dividing unit in the set.

Abstract: A phase locked loop (PLL) includes a multiplexer (MUX), a phase detector, a filter block, an oscillator, a frequency divider, and a clock switch controller, and achieves hitless switching between a primary clock and a redundant clock. The clock switch controller, upon detecting a condition requiring switching from the primary clock to the redundant clock, is operable to restart the feedback divider synchronously with respect to the redundant clock, and derive the output of the PLL from the redundant clock. The PLL further includes a delay block to process delayed phase error signals generated by the phase detector. The PLL performs hitless clock switching in the event of input clock loss or in response to a command to switch input clocks. The PLL further includes circuitry for estimating and cancelling residual phase errors.

Abstract: A frequency divider includes a set of frequency-dividing units coupled in series in a sequential order, with the sequence of frequency-dividing units including a lowest unit and a highest unit, with the remaining units being disposed in series between the lowest unit and the highest unit. The lowest unit is coupled to receive an input clock whose frequency is to be divided and provided as an output clock. Each frequency-dividing unit in the set is coupled to receive a corresponding first clock as an input and is operable to generate a corresponding second clock as an output. The frequency divider includes a logic block to generate a first set of edges of the output clock synchronous with the input clock. The logic block is designed to generate a second set of edges of the output clock synchronous with the output clock of a highest operative frequency-dividing unit in the set.

Abstract: A phase locked loop (PLL) includes a multiplexer (MUX), a phase detector, a filter block, an oscillator, a frequency divider, and a clock switch controller, and achieves hitless switching between a primary clock and a redundant clock. The clock switch controller, upon detecting a condition requiring switching from the primary clock to the redundant clock, is operable to restart the feedback divider synchronously with respect to the redundant clock, and derive the output of the PLL from the redundant clock. The PLL further includes a delay block to process delayed phase error signals generated by the phase detector. The PLL performs hitless clock switching in the event of input clock loss or in response to a command to switch input clocks. The PLL further includes circuitry for estimating and cancelling residual phase errors.

Abstract: A phase frequency detector (PFD) includes a first circuit portion and a second circuit portion. The first circuit portion receives a reference signal and activates a first error signal if the phase of the reference frequency leads the phase of a feedback signal. The second circuit portion receives the reference and activates a second error signal if the phase of the reference frequency lags the phase of the feedback signal. The first circuit portion is powered by a first power supply, and the second circuit portion is powered by a second power supply. A PLL implemented using the PFD generates a frequency output with minimized jitter.

Abstract: A method for distributing coupons through a network and online coupon distribution network, including the steps of: (a) storing offers and coupon codes from sellers on a coupon distribution server; (b) installing and configuring a web widget in a first seller's ecommerce store server; (c) displaying on the web widget at a shopper's terminal, offers or coupon codes from one or more other sellers in the coupon exchange network; (d) allowing a shopper to select or request one or more of the displayed offers or coupon codes; (e) sending from the coupon distribution server, the coupon code associated with the selected offer to the shopper terminal; and (f) recording transaction information about the shopper and selected offer. The invention also provides for the ranking of sellers in the network to control the display of the seller's offers and coupons.

Abstract: A divider circuit determines whether an input factor (N) is an even number or an odd number. If N is an even number then the input clock is divided by N/2 to generate an intermediate clock. The intermediate clock is further divided by two to generate a div-by-2 clock, which is provided as the output clock with fifty percent duty cycle. If N is an odd number, the input clock is divided by (N/2?0.5) in a first duration and by (N/2+0.5) in a second duration to generate the intermediate clock, which is then divided by two to generate the div-by-2 clock. A delayed clock is generated from the div-by-2 clock, wherein the delayed clock lags the div-by-2 clock by half cycle duration of the input clock. The div-by-2 clock and the delayed clock are combined to generate the output clock with fifty percent duty cycle.

Abstract: A divider circuit determines whether an input factor (N) is an even number or an odd number. If N is an even number then the input clock is divided by N/2 to generate an intermediate clock. The intermediate clock is further divided by two to generate a div-by-2 clock, which is provided as the output clock with fifty percent duty cycle. If N is an odd number, the input clock is divided by (N/2?0.5) in a first duration and by (N/2+0.5) in a second duration to generate the intermediate clock, which is then divided by two to generate the div-by-2 clock. A delayed clock is generated from the div-by-2 clock, wherein the delayed clock lags the div-by-2 clock by half cycle duration of the input clock. The div-by-2 clock and the delayed clock are combined to generate the output clock with fifty percent duty cycle.

Abstract: A low phase-noise phase locked loop (PLL). In an embodiment, the PLL includes a charge pump that includes a first switch, a second switch, a first resistor and a second resistor, which are connected in series. The first switch is provided between a power supply node and the first resistor, while the second switch is provided between the second resistor and a ground node. The junction of the first resistor and the second resistor provides the output of the charge pump. The first switch and the second switch are operated to be open or closed by outputs of a phase frequency detector of the PLL. In another embodiment, the charge pump and the low-pass filter of the PLL are implemented to process differential signals. Such implementation of the charge pump enables the PLL to generate an output signal with reduced phase-noise.

Abstract: A phase frequency detector (PFD) includes a first circuit portion and a second circuit portion. The first circuit portion receives a reference signal and activates a first error signal if the phase of the reference frequency leads the phase of a feedback signal. The second circuit portion receives the reference and activates a second error signal if the phase of the reference frequency lags the phase of the feedback signal. The first circuit portion is powered by a first power supply, and the second circuit portion is powered by a second power supply. A PLL implemented using the PFD generates a frequency output with minimized jitter.

Abstract: A programmable frequency divider includes a cascade of frequency-dividing units, each capable of dividing by a first or a second factor. Each unit receives an input clock and generates a divided output clock. Each unit receives a mode control signal that specifies when to divide its input clock by the second factor if a control input allows it, otherwise dividing the input clock by the first factor. The frequency divider is designed to support a range of divide ratios that requires one or more of the units to be non-operative or unused in some intervals. The final divided clock is generated using the mode control signal of the lowest unit in the cascade and the mode control signal of the highest unit that is never set to be non-operative or unused in supporting the range. As a result, duty-cycle variations of the final divided clock are minimized.

Abstract: An embodiment of the invention provides a sliced transmitter front-end (TX FE). The sliced TX FE includes first TX FE slices and a second TX FE slice that are connected in parallel. As a whole the first TX FE slices contributes a high-gain section to a superimposed gain range of the sliced TX FE. The second TX FE slice has a gain range that constitutes a low-gain section of the superimposed gain range of the sliced TX FE. A minimum gain of the gain range of the second TX FE slice is smaller than a minimum gain of the high-gain section.

Abstract: A tunable inductor includes a main wiring and at least one tuning module. The main wiring is arranged to encircle an inductor area of the tunable inductor. In addition, the tuning module is arranged to couple associated nodes of the main wiring. For example, each tuning module of the at least one tuning module includes a first switch positioned within the inductor area, and further includes at least one auxiliary wiring. When the first switch is turned on, the tuning module couples two nodes of the main wiring, where the at least one auxiliary wiring is arranged to couple the two nodes when the first switch is turned on. In particular, a patterned ground plane is arranged to decrease the energy loss of the tunable inductor, and more particularly, to prevent the tunable inductor from suffering energy loss. The patterned ground plane includes some conductive sections forming a W-like shape.

Abstract: An integrated circuit device includes at least one controllable oscillator including a first control port and at least one further control port, at least one frequency control module including an output arranged to provide a frequency control signal. The at least one controllable oscillator further includes at least one compensation module including an output arranged to provide at least one compensation signal. The at least one compensation module includes an integrator component arranged to receive at an input thereof a signal that is representative of a difference between the indication of the frequency control signal and a reference signal, and to output an integrated difference signal. The at least one compensation module is arranged to generate the at least one compensation signal based at least partly on the integrated difference signal output by the integrator component.

Abstract: A clock generating apparatus includes: a time-to-digital converter (TDC) arranged to convert a timing difference between a reference clock and a variable clock to generate a digital value; a calibrating device arranged to generate a control signal according to the digital value and the reference clock; a controllable oscillator arranged to generate an oscillating signal according to the control signal and the digital value; and a feedback device arranged to generate the variable clock to the TDC according to the oscillating signal, and the calibrating device calibrates the controllable oscillator to make the oscillating signal have a target oscillating frequency.

Abstract: A digitally controlled oscillator is provided. The digitally controlled oscillator includes a pair of transistors cross-coupled to each other, a switched capacitor array coupled to the pair of transistors and a plurality of frequency tracking units coupled to the pair of transistors. The pair of transistors provides an output signal. The switched capacitor array tunes a frequency of the output signal. The frequency tracking units tune the frequency of the output signal to a target frequency. At least one of the frequency tracking units is capable of selectively providing a first capacitance and a second capacitance. A tuning resolution of the frequency tracking unit is determined by a difference between the first and second capacitances.

Abstract: A temperature compensation circuit includes: a sensing circuit arranged to sense a temperature to generate a sensing signal; an operational circuit arranged to sample the sensing signal to generate a sample signal during a first phase, and arranged to generate an output signal according to the sensing signal and the sample signal during a second phase; and a capacitive circuit arranged to provide a capacitance adjusted by the output signal.

Abstract: An embodiment of the invention provides a sliced transmitter front-end (TX FE). The sliced TX FE includes first TX FE slices and a second TX FE slice that are connected in parallel. As a whole the first TX FE slices contributes a high-gain section to a superimposed gain range of the sliced TX FE. The second TX FE slice has a gain range that constitutes a low-gain section of the superimposed gain range of the sliced TX FE. A minimum gain of the gain range of the second TX FE slice is smaller than a minimum gain of the high-gain section.