Abstract: Disclosed herein is a DC-DC converter including a power section and a bootstrap circuit for driving the gate of the high-side transistor of the power section. The bootstrap circuit includes an adaptive clamp circuit that maintains a proper voltage differential across the bootstrap capacitor within the bootstrap circuit for recharge during off-times regardless of whether the mode of operation of the DC-DC converter continuous conduction mode (CCM), discontinuous conduction mode (DCM), or pulse-skip mode. This voltage differential is established as being between a bootstrap voltage and a voltage at a tap between the high and low side transistors of the power section. The adaptive clamp circuit maintains the bootstrap voltage as following the lesser of the output voltage and the voltage at the tap.

Abstract: A method includes, for each optical fiber path in an optical network, allocating an optical wavelength channel in an optical spectrum such that the allocated optical wavelength channel is assigned to support optical communications over the optical fiber path. The method also includes updating an allocation table in response to performing the allocating for one or more of the optical fiber paths; the allocating including determining the optical wavelength channel to be allocated based on a state of the allocation table. The allocation table indicates optical wavelength channels allocated over optical fiber spans of the optical network. The method also includes defining a set of optical sub-bands to cover a part of the optical spectrum in response to a state of the allocation table satisfying a fullness property. The optical sub-bands are such that each of the allocated wavelength channels is in one of the optical sub-bands.

Abstract: Disclosed herein is a DC-DC converter including a power section and a bootstrap circuit for driving the gate of the high-side transistor of the power section. The bootstrap circuit includes an adaptive clamp circuit that maintains a proper voltage differential across the bootstrap capacitor within the bootstrap circuit for recharge during off-times regardless of whether the mode of operation of the DC-DC converter continuous conduction mode (CCM), discontinuous conduction mode (DCM), or pulse-skip mode. This voltage differential is established as being between a bootstrap voltage and a voltage at a tap between the high and low side transistors of the power section. The adaptive clamp circuit maintains the bootstrap voltage as following the lesser of the output voltage and the voltage at the tap.

Abstract: A charge pump circuit is provided, comprising: a first charge pump having an input terminal for receiving a supply voltage and configured to boost the received supply voltage to provide at an output terminal of the first charge pump a first charge pump voltage; a second charge pump having an input terminal coupled to the output terminal of the first charge pump for receiving the first charge pump voltage and configured to boost the received first charge pump voltage to provide at an output terminal of the second charge pump a second charge pump voltage, and a voltage drop sensing device configured to detect drops in the first charge pump voltage and to deactivate second transistors of bypass units associated to the disabled charge pump stages when a drop in the first charge pump voltage is detected.

Abstract: A charge pump circuit is provided, comprising: a first charge pump having an input terminal for receiving a supply voltage and configured to boost the received supply voltage to provide at an output terminal of the first charge pump a first charge pump voltage; a second charge pump having an input terminal coupled to the output terminal of the first charge pump for receiving the first charge pump voltage and configured to boost the received first charge pump voltage to provide at an output terminal of the second charge pump a second charge pump voltage, and a voltage drop sensing device configured to detect drops in the first charge pump voltage and to deactivate second transistors of bypass units associated to the disabled charge pump stages when a drop in the first charge pump voltage is detected.

Abstract: A non-volatile memory device comprises memory cells, a first regulator, a second regulator, a first switch, a second switch and capacitor coupling switches. The first regulator comprises a first capacitor, and generates a first voltage at a first node connected to a first subset of the memory cells, to provide the first voltage to the first subset. The second regulator comprises a second capacitor, and generates a second voltage at a second node. The first switch selectively couples the second node to a second subset of the memory cells, to provide the second voltage to the second subset. The second switch selectively couples the first node to the second subset to also provide the first voltage to the second subset. The capacitor coupling switches selectively couple the second capacitor in parallel to the first capacitor when the first switch is deactivated, and the second switch is activated.

Abstract: A memory device comprises memory cells, a first regulator, a second regulator, a first switch, a second switch and capacitor coupling switches. The first regulator comprises a first capacitor, and generates a first voltage at a first node connected to a first subset of the memory cells, to provide the first voltage to the first subset. The second regulator comprises a second capacitor, and generates a second voltage at a second node. The first switch selectively couples the second node to a second subset of the memory cells, to provide the second voltage to the second subset. The second switch selectively couples the first node to the second subset to also provide the first voltage to the second subset. The capacitor coupling switches selectively couple the second capacitor in parallel to the first capacitor when the first switch is deactivated, and the second switch is activated.

Abstract: A method includes, for each optical fiber path in an optical network, allocating an optical wavelength channel in an optical spectrum such that the allocated optical wavelength channel is assigned to support optical communications over the optical fiber path. The method also includes updating an allocation table in response to performing the allocating for one or more of the optical fiber paths; the allocating including determining the optical wavelength channel to be allocated based on a state of the allocation table. The allocation table indicates optical wavelength channels allocated over optical fiber spans of the optical network. The method also includes defining a set of optical sub-bands to cover a part of the optical spectrum in response to a state of the allocation table satisfying a fullness property. The optical sub-bands are such that each of the allocated wavelength channels is in one of the optical sub-bands.

Abstract: Described is a method of transmitting an optical signal in an optical transmission system. The method comprises: providing a length of an optical fiber having a zero chromatic dispersion wavelength, wherein the optical fiber belongs to an optical fiber group and wherein the optical fiber group comprises optical fibers having a zero chromatic dispersion wavelength comprised within a wavelength range; estimating a tolerated chromatic dispersion range; and transmitting the optical signal over the length of optical fiber at a first transmission wavelength.

Abstract: Described is a method of transmitting an optical signal in an optical transmission system. The method comprises: providing a length of an optical fiber having a zero chromatic dispersion wavelength, wherein the optical fiber belongs to an optical fiber group and wherein the optical fiber group comprises optical fibers having a zero chromatic dispersion wavelength comprised within a wavelength range; estimating a tolerated chromatic dispersion range; and transmitting the optical signal over the length of optical fiber at a first transmission wavelength.

Abstract: The invention relates to a method of reducing the intensity distortion induced by cross phase modulation in a wavelength division multiplexed optical fiber transmission system comprising a transmission line made up of a plurality of optical fiber segments with repeaters interposed between successive optical fiber segments, the transmission system having N different wavelength channels, where N is an integer greater than unity. In each repeater interconnecting first and second consecutive fiber segments, a time offset is introduced between the channels in such a manner that compared with the inlet of the first optical segment, the (n+1)th and the nth channels are offset by &tgr;n at the inlet to the second fiber segment, where n is an integer less than or equal to N, where &tgr;n is selected to be greater than zero and less than a value that eliminates correlation between the intensity distortion contributions of each fiber segment.

Abstract: Automatic device for packing in a container, of the strip provided by a carding unit, consisting of an eccentric distributor which rotates relative to the collection container, which is rotated by an underlying rotary platform, and also comprises a device for movement and centring of the collection containers.