Patent application number | Description | Published |
20110029697 | MEMORY DEVICES IMPLEMENTING CLOCK MIRRORING SCHEME AND RELATED MEMORY SYSTEMS AND CLOCK MIRRORING METHODS - A memory device is configured to operate in first and second data input/output modes. The memory device includes a first electrode pad, a second electrode pad, a clock signal line, a first switching unit, and a second switching unit. The clock signal line is configured to transmit a clock to an integrated circuit inside the memory device. The first switching unit switches to electrically connect the first electrode pad and the clock signal line in response to a control signal occurring for the first data input/output mode. The second switching unit switches to electrically connect the second electrode pad and the clock signal line in response to an inverse signal of the control signal occurring for the second data input/output mode. | 02-03-2011 |
20110185219 | MEMORY DEVICES IMPLEMENTING CLOCK MIRRORING SCHEME AND RELATED MEMORY SYSTEMS AND CLOCK MIRRORING METHODS - A memory device is configured to operate in first and second data input/output modes. The memory device includes a first electrode pad, a second electrode pad, a clock signal line, a first switching unit, and a second switching unit. The clock signal line is configured to transmit a clock to an integrated circuit inside the memory device. The first switching unit switches to electrically connect the first electrode pad and the clock signal line in response to a control signal occurring for the first data input/output mode. The second switching unit switches to electrically connect the second electrode pad and the clock signal line in response to an inverse signal of the control signal occurring for the second data input/output mode. | 07-28-2011 |
20110249513 | TRANSMITTING/RECEIVING METHODS AND SYSTEMS WITH SIMULTANEOUS SWITCHING NOISE REDUCING PREAMBLES - DC balance encoded data is transmitted by transmitting a preamble of dummy data that is configured to provide an intermediate number of bits of a given logic value that is at least one bit of the given logic value but less than a maximum number of bits of the given logic value in the DC balance encoded data, to thereby reduce the simultaneous switching noise that is caused by transmission of a first word of DC balance encoded data. The preamble may contain one or more words of fixed and/or variable dummy data. | 10-13-2011 |
Patent application number | Description | Published |
20080225623 | MEMORY DEVICES IMPLEMENTING CLOCK MIRRORING SCHEME AND RELATED MEMORY SYSTEMS AND CLOCK MIRRORING METHODS - A memory device is configured to operate in first and second data input/output modes. The memory device includes a first electrode pad, a second electrode pad, a clock signal line, a first switching unit, and a second switching unit. The clock signal line is configured to transmit a clock to an integrated circuit inside the memory device. The first switching unit switches to electrically connect the first electrode pad and the clock signal line in response to a control signal occurring for the first data input/output mode. The second switching unit switches to electrically connect the second electrode pad and the clock signal line in response to an inverse signal of the control signal occurring for the second data input/output mode. | 09-18-2008 |
20090097339 | Integrated Circuit Memory Devices Having Internal Command Generators Therein that Support Extended Command Sets Using Independent and Dependent Commands - Integrated circuit memory devices include an internal command generator and a memory control circuit responsive to an internal command generated by the internal command generator. The internal command generator is configured to generate an internal command in response to a combination of an independent command and at least one dependent command received in sequence by the memory device. For example, the internal command generator may be configured to require the independent command to follow the at least one dependent command in the sequence when generating the internal command from the combination of the independent and dependent commands. Alternatively, the internal command generator may be configured to require the independent command to precede the at least one dependent command in the sequence before generating the internal command from the combination of the independent and dependent commands. These independent and dependent commands may be received by the memory device as respective multi-bit external command signals. | 04-16-2009 |
20090102523 | LINEAR DIGITAL PHASE INTERPOLATOR AND SEMI-DIGITAL DELAY LOCKED LOOP (DLL) - Provided are a digital phase interpolator, which performs linear phase interpolation irrelevantly to input order of two input signals, and a semi-digital delay locked loop (DLL), which includes and controls the same. The phase interpolator includes: a first clocked inverter controlled by a phase indicating signal and providing a first output signal to a common output terminal by inverting a first input signal, and a second clocked inverter controlled by the phase indicating signal and providing a second output signal to the common output terminal by inverting the second input signal. The second clocked inverter is clocked by the first input signal when the phase indicating signal is in a first logic state, and the first clocked inverter is clocked by the second input signal when the phase indicating signal is in a second logic state. The phase indicating signal indicates a lead/lag phase relationship between the first and second input signals and is generated in a controller of a circuit of the semi-digital DLL. | 04-23-2009 |
20090146850 | TRANSMITTING/RECEIVING METHODS AND SYSTEMS FOR DC BALANCE ENCODED DATA INCLUDING SIMULTANEOUS SWITCHING NOISE REDUCING PREAMBLES - DC balance encoded data is transmitted by transmitting a preamble of dummy data that is configured to provide an intermediate number of bits of a given logic value that is at least one bit of the given logic value but less than a maximum number of bits of the given logic value in the DC balance encoded data, to thereby reduce the simultaneous switching noise that is caused by transmission of a first word of DC balance encoded data. The preamble may contain one or more words of fixed and/or variable dummy data. | 06-11-2009 |
20100259426 | TRANSMITTING/RECEIVING METHODS AND SYSTEMS WITH SIMULTANEOUS SWITCHING NOISE REDUCING PREAMBLES - DC balance encoded data is transmitted by transmitting a preamble of dummy data that is configured to provide an intermediate number of bits of a given logic value that is at least one bit of the given logic value but less than a maximum number of bits of the given logic value in the DC balance encoded data, to thereby reduce the simultaneous switching noise that is caused by transmission of a first word of DC balance encoded data. The preamble may contain one or more words of fixed and/or variable dummy data. | 10-14-2010 |
20110135030 | Semiconductor device, a parallel interface system and methods thereof - A semiconductor device, a parallel interface system and methods thereof are provided. The example semiconductor device may include a reference clock transmitting block generating a reference clock signal, a plurality of first transceiver blocks, each of the plurality of first transceiver blocks transmitting at least one parallel data bit signal based on one of a plurality of phase-controlled transmitting sampling clock signals and a per-pin deskew block controlling a phase of a transmitting sampling clock signal to generate the phase-controlled sampling clock signals for the respective plurality of transceiver blocks, the per-pin deskew block controlling the phase of each phase-controlled transmitting sampling clock signal based on a phase skew between a given training data bit signal, among a plurality of training data bit signals, corresponding to a given first transceiver block and the reference clock signal in a first operation mode, and based on phase skew information relating to a phase skew between a given parallel data bit signal of the at least one parallel data bit signal and the reference clock signal in a second operation mode. An example method may include reducing skew based on a comparison between a plurality of transmitted training data bit signals and a corresponding plurality of received training data bit signals in a first mode of operation and reducing skew based on received phase skew information relating to a phase skew difference between a reference signal and a parallel data bit signal in a second mode of operation. | 06-09-2011 |
20130100998 | SEMICONDUCTOR DEVICE, A PARALLEL INTERFACE SYSTEM AND METHODS THEREOF - A method of communication to a semiconductor device includes: transmitting a sampling clock signal from a first semiconductor device to a second semiconductor device; transmitting a training signal from the first semiconductor device to the second semiconductor device while transmitting of the sampling clock signal, the training signal comprising plural test patterns sent sequentially to the second semiconductor device, phases of at least some of the test patterns being adjusted to be different from each other during transmitting of the training signal; receiving first information from the second semiconductor device over a first signal line, the first signal line separate from a data bus connected between the first semiconductor device and the second semiconductor device; and transmitting a data signal over the data bus while transmitting the sampling clock signal, the data signal sent at a timing with respect to the sampling clock signal responsive to the received first information. | 04-25-2013 |
Patent application number | Description | Published |
20080278193 | Reference voltage generators for reducing and/or eliminating termination mismatch - A system including a plurality of transmission lines, a transmitter outputting respective signals to each of the plurality of transmission lines, a receiver receiving each of the plurality of signals via respective transmission lines, the receiver including a connection path connected to a termination voltage, a plurality of termination circuits distributed along the connection path, each termination circuit receiving a unique termination voltage from the connection path, receiving a respective signal and outputting a terminated input signal, a reference voltage generator including multiple reference voltage generator units connected to a common voltage, each reference voltage generator unit uniquely receiving at least one unique termination voltage and outputting a reference voltage, and a plurality of data input buffers receiving respective signals and an appropriate reference voltage of the multiple reference voltages output from the reference voltage generator. | 11-13-2008 |
20090174445 | Semiconductor devices, methods of operating semiconductor devices, and systems having the same - A semiconductor device includes a selection circuit and a phase detector. The selection circuit, in response to a first selection signal output from a controller, outputs as a timing signal a first clock signal output from the controller or an output signal of a PLL using the first clock signal as a first input. The phase detector generates a voltage signal indicating a phase difference between a second clock signal output from the controller and the timing signal output from the selection circuit. The semiconductor device further includes a data port, a memory core storing data, and a serializer, in response to the timing signal output from the selection circuit, serializing the data output from the memory core and outputting serialized data to the controller via the data port. The first selection signal is generated by the controller based on at least one of the voltage signal and the data output to the controller via the data port. | 07-09-2009 |
20090219179 | Single ended pseudo differential interconnection circuit and single ended pseudo differential signaling method - A single ended pseudo differential signaling method may add a 1-bit signal to n-bit data if transmitting the n-bit data. Neighboring two signals among the 1-bit signal and data signals are compared to each other to generate detection signals. | 09-03-2009 |
20090267813 | Semiconductor devices, a system including semiconductor devices and methods thereof - Semiconductor devices, a system including said semiconductor devices and methods thereof are provided. An example semiconductor device may receive data scheduled for transmission, scramble an order of bits within the received data, the scrambled order arranged in accordance with a given pseudo-random sequence. The received data may be balanced such that a difference between a first number of the bits within the received data equal to a first logic level and a second number of bits within the received data equal to a second logic level is below a threshold. The balanced and scrambled received data may then be transmitted. The example semiconductor device may perform the scrambling and balancing operations in any order. Likewise, on a receiving end, another semiconductor device may decode the original data by unscrambling and unbalancing the transmitted data. The unscrambling and unbalancing operations may be performed in an order based upon the order in which the transmitted data is scrambled and balanced. | 10-29-2009 |
20100148819 | Majority voter circuits and semiconductor device including the same - A majority voter circuit is configured to generate a selecting signal based on first input data and inverted first input data. The first input data and the inverted first input data each include an odd-number of bits, and the odd-number of bits include bits of a first type and bits of a second type. The generated selecting signal is indicative of which of the first type and the second type of bits in the first input data are in the majority. | 06-17-2010 |
20110128170 | Semiconductor devices, a system including semiconductor devices and methods thereof - Semiconductor devices, a system including said semiconductor devices and methods thereof are provided. An example semiconductor device may receive data scheduled for transmission, scramble an order of bits within the received data, the scrambled order arranged in accordance with a given pseudo-random sequence. The received data may be balanced such that a difference between a first number of the bits within the received data equal to a first logic level and a second number of bits within the received data equal to a second logic level is below a threshold. The balanced and scrambled received data may then be transmitted. The example semiconductor device may perform the scrambling and balancing operations in any order. Likewise, on a receiving end, another semiconductor device may decode the original data by unscrambling and unbalancing the transmitted data. The unscrambling and unbalancing operations may be performed in an order based upon the order in which the transmitted data is scrambled and balanced. | 06-02-2011 |
20130064030 | SEMICONDUCTOR DEVICES, METHODS OF OPERATING SEMICONDUCTOR DEVICES, AND SYSTEMS HAVING THE SAME - A semiconductor device includes a selection circuit and a phase detector. The selection circuit, in response to a first selection signal output from a controller, outputs as a timing signal a first clock signal output from the controller or an output signal of a PLL using the first clock signal as a first input. The phase detector generates a voltage signal indicating a phase difference between a second clock signal output from the controller and the timing signal output from the selection circuit. The semiconductor device further includes a data port, a memory core storing data, and a serializer, in response to the timing signal output from the selection circuit, serializing data output from the memory core and outputting serialized data to the controller via the data port. The controller generates the first selection signal based on at least one of the voltage signal and the serialized data. | 03-14-2013 |
20130135956 | SEMICONDUCTOR DEVICE, A PARALLEL INTERFACE SYSTEM AND METHODS THEREOF - A memory device includes a clock receiving block, a data transceiver block, a phase detection block, and a phase information transmitter. The clock receiving block is configured to receive a clock signal from a memory controller through a clock signal line and generate a data sampling clock signal and an edge sampling clock signal. The data transceiver block is configured to receive a data signal from the memory controller through a data signal line. The phase detection block is configured to generate phase information in response to the data sampling clock signal, the edge sampling clock signal and the data signal. The phase information transmitter is configured to transmit the phase information to the memory controller through a phase information signal line that is separate from the data signal line. | 05-30-2013 |