| Patent application number | Description | Published |
|---|
| 20080225987 | Asynchronous interconnection system for 3D interchip communication - An embodiment of the present invention relates to a asynchronous interconnection system comprising a transmitter circuit and a receiver circuit inserted between inserted between respective first and second voltage references and having respective transmitter and receiver nodes coupled in a capacitive manner. The receiver circuit comprises: a recovery stage inserted between the first and second voltage references of the receiver circuit and connected to the receiver node; and a state control stage, in turn inserted between the first and second voltage references of the receiver circuit connected to the recovery stage correspondence with a first feedback node providing a first control signal and having a second feedback node connected in a feedback manner to the recovery stage. The recovery stage comprises a first feedback loop connected to the first feedback node and acting in such a way to recover a received voltage signal and a feedback loop connected to the second feedback node of the state control stage and acting in such a way to deactivate the recovery feedback on the receiver node and guarantee that the receiver node is let in a high impedance state. | 09-18-2008 |
| 20090168860 | COMMUNICATION SYSTEM BETWEEN A FIRST AND A SECOND SYNCHRONOUS DEVICE THAT ARE UNCORRELATED IN TIME - A communication system includes first and second independently clocked devices, comprising, for each device, a transmitter and a receiver connected to each other in a crossed way in correspondence of an inter-chip communication channel. The communication system further comprises a synchronizer in turn including at least a first and a second synchronization block, having respective input terminals connected to the receivers and respective output terminals connected to the transmitters and comprising at least: a test pattern generator that generates a programmable test pattern signal; a pattern detector to check a matching between stored and received test pattern signals and thus lock corresponding clock phases of the synchronization blocks in case of positive result of this check; and a delay block able to change the clock phases until a synchronized condition of the synchronization blocks is verified, this synchronized condition corresponding to a matching between stored and received test pattern signals. | 07-02-2009 |
| 20090168938 | COMMUNICATION SYSTEM FOR CONNECTING SYNCHRONOUS DEVICES THAT ARE UNCORRELATED IN TIME - A communication system for the connection between timing non-correlated synchronous devices comprising at least one transmitter and one receiver inserted between a first and a second voltage reference and connected to each other through a transmission channel in correspondence with respective transmitting and receiving terminals Advantageously, the receiver comprises at least one asynchronous input stage suitable for receiving on the receiving terminal a datum and associated with a synchronous output stage suitable for transmitting this datum in a synchronized way with a clock signal on a synchronized receiving terminal. A method transmits a datum from a transmitter to a receiver interconnected by a capacitive channel in a communication system for the connection between independently clocked devices. | 07-02-2009 |
| 20110171906 | COMMUNICATION CELL FOR AN INTEGRATED CIRCUIT, CHIP COMPRISING SAID COMMUNICATION CELL, ELECTRONIC SYSTEM INCLUDING THE CHIP, AND TEST APPARATUS - An embodiment of communication cell for enabling data communication between an integrated circuit and an electronic unit distinct from the integrated circuit, comprising a contact pad unit, configured for capacitively coupling, in a first operating condition of said communication cell, to the electronic unit for receiving an input signal from said electronic unit, and for ohmically coupling, in a second operating condition of said communication cell, to the electronic unit for receiving the input signal; a receiver device, including signal-amplifying means, coupled between said contact pad unit and said integrated circuit, configured for receiving the input signal and generating an intermediate signal correlated to the input signal; signal-selection means receiving the intermediate signal, the input signal, and providing an output signal which is the intermediate signal during the first operating condition, and the input signal during the second operating condition; and an input stage, connectable between the integrated circuit and the output terminal of the signal-selection means, configured for receiving the output signal and providing the output signal to the integrated circuit. | 07-14-2011 |
| 20110319014 | ELECTRONIC CIRCUIT FOR COMMUNICATING THROUGH CAPACITIVE COUPLING - A device and method to compensate for distortions of amplitude that afflict systems for communicating through capacitive coupling. A circuit includes a first transmitter stage, a first receiver stage, and a first coupling capacitor, coupled between the first transmitter stage and the first receiver stage. The first receiver stage includes a calibration amplifier of a variable-gain type coupled between the first coupling capacitor and an output of the electronic circuit. The electronic circuit includes a reference channel formed by: a transmission calibration stage; a reception calibration stage; and a reference capacitor coupled between the transmission calibration stage and the reception calibration stage. The reception calibration stage includes: a reception amplifier of a variable-gain type, having an input coupled to the reference capacitor, and a gain controller, having an input coupled to an output of the reception amplifier and an output coupled to control terminals of the reception and calibration amplifiers. | 12-29-2011 |
| 20110319015 | METHOD FOR VERIFYING THE ALIGNMENT BETWEEN INTEGRATED ELECTRONIC DEVICES - A method for verifying alignment between first and second integrated devices coupled together using a reference and a coupling capacitor, including: transmitting a reference signal on a transmission electrode of the reference capacitor; receiving a coupling signal on a reception electrode of the reference capacitor; amplifying the coupling signal, generating a reception reference signal; generating a reception control signal as a function of the reception reference signal; transmitting a communication signal on an electrode of the coupling capacitor; receiving a reception signal on an electrode of the coupling capacitor; amplifying the reception signal, generating a first compensated signal; controlling a level of amplification of amplifying the coupling signal and the reception signal as a function of the reception control signal; and detecting a possible misalignment between the first and second devices based on an amplitude of the communication signal and an amplitude of the compensated signal. | 12-29-2011 |
| 20120001655 | BASE CELL FOR IMPLEMENTING AN ENGINEERING CHANGE ORDER (ECO) - A circuit base cell is for implementing an engineering change order (ECO) obtained on a semiconductor substrate. The base cell may include a PMOS transistor having a first active region obtained in a first diffusion P+ layer implanted in an N-well provided for on the substrate, and an NMOS transistor having a second active region obtained in a second diffusion N+ layer implanted on the substrate in such a manner as to be electrically insulated from the first diffusion P+ layer. The cell may be characterized in that the active regions and the diffusion layers are aligned therebetween with respect to a reference axis and they are extended symmetrically in the direction orthogonal to the axis. A first and a second width may be associated with the active regions and to the diffusion layers, respectively. The first and second width may be greater than a width of the cell, which is equivalent to a pitch of the standard minimum cell. | 01-05-2012 |
