A random number generating circuit includes M random number generators, where M is an integer greater than or equal to 2, configured to be independent of each other and generate M random number sequences, a delay adjustment circuit configured to output N sets of the M random number sequences including N different relative time differences or N different combinations of a plurality of relative time differences, where N is an integer greater than or equal to 2, by adjusting one or more relative time differences between the M random number sequences, and a logic operation circuit configured to perform an exclusive OR operation between the M random number sequences included in a set, for each of the N sets of the M random number sequences.

A measurement system may measure a fractional time delay of transmission of a signal across a medium, such as a cable. The system may use a first clock to assist in creating and injecting an injected sequence (signal) into the medium. A second, slower clock may be used for sampling the sequence after transmission of the sequence through the medium. This causes a time Vernier scale effect that results in a sampled sequence that has a one-step skip for each instances of the sequence, where the sequence has N elements in the sequence. The location of the skip within the sequence will depend on the magnitude of the delay measured as a fraction of a clock period with a resolution of N. To measure this delay, a modified version of a pseudo-random sequence generator, capable of skipping one step, is used to determine the output.

A method for generating M parallel pseudorandom binary sequences (PRBSs), each comprising a 2.sup.n1 sequence of pseudorandom bits, includes loading into the circuit an initial M-bit word, the initial M-bit word comprising M sequential bits selected from a pre-determined PRBS-n sequence, wherein n>1 and M>n. The method includes generating, using a plurality of logic gates of the circuit, a next M-bit word using at least n+1 of the M sequential bits of the initial M-bit word. The method includes repeatedly generating, using the logic gates of the circuit, the next M-bit word from a previous M-bit word using the at least n+1 of M sequential bits of the previous M-bit word, resulting in M parallel sequences of the PRBS-n sequence. The method includes transmitting the generated next M-bit words on an M-bit wide parallel bus.

The invention relates to the field of computer engineering and cryptography and, in particular, to methods for implementing linear transformations that operate with a specified speed and require minimum amount of memory, for further usage in devices for cryptographic protection of data. The technical result enables the selection of interrelated parameters (performance and required amount of memory) for a particular computing system when implementing a high-dimensional linear transformation. The use of the present method allows for a reduction of the amount of consumed memory at a given word size of processors employed. To this end, based on a specified linear transformation, a modified linear shift register of Galois-type or Fibonacci-type is generated according to the rules provided in the disclosed method, and the usage thereof enables to obtain the indicated technical result.

According to one embodiment, an apparatus is capable of exchanging a frame with an external apparatus in a packet mode of a serial attached small computer system interface (SAS). The external apparatus includes a scrambler. The apparatus includes a descrambler and a controller. The descrambler is configured to descramble frame data scrambled by the scrambler. The controller is configured to, in a case where first frame data is received from the external apparatus, synchronize the descrambler with the scrambler using the first frame data and a first value that is to be scrambled by the scrambler to obtain the first frame data.

An apparatus having a power bus supplying power to a component of a memory device. The apparatus includes a noise source circuit generating a plurality of noise source signals that simulate a real-world noise. The apparatus can include a pulse generator circuit that receives the noise source signal and outputs at least one noise profile signal based on the noise source signal. A bus shorting circuit can be connected to the pulse generator circuit to receive the at least one noise profile signal. The bus shorting circuit can have at least one transistor connected between a first rail and a second rail of the power bus. Based on the at least one noise profile signal, the bus shorting circuit intermittently connects the at least one transistor between the first rail to the second rail to induce noise on the power bus.

A system and method of generating a series of random number; from a source of random numbers in a computing system. Steps includes: loading a data loop (a looped array of stored values with an index) with random data from a source of random data; then repeating the following: reading a value from the data loop in relation to the index; operating on the multi-bit value thereby outputting a derived random number; and moving the index in relation to the looped array. The data loop may be a simple feedback loop which may be a shift register loaded by direct memory access (DMA). The operation may be performed by one or more arithmetic logic units (ALU) which may be fed by one or more data feeds and may perform XOR, Mask Generator, Data MUX, and/or MOD.

A true random number generation device and a true random number generation method are provided. The true random number generation device includes a selection signal providing circuit and a linear feedback shift register. The selection signal providing circuit is configured to provide a true random selection signal. The linear feedback shift register includes true random number generators of a plurality of stages. The Nth stage true random number generator is configured to receive a clock signal and a N1th bit true random number. The Nth stage true random number generator generates a plurality of Nth stage output logic values according to the clock signal and the N1th bit true random number, and selects one of the plurality of Nth stage output logic values to be a Nth bit true random number according to the true random selection signal.

A method for generating M parallel pseudorandom binary sequences (PRBSs), each comprising a 2.sup.n1 sequence of pseudorandom bits, includes loading into the circuit an initial M-bit word, the initial M-bit word comprising M sequential bits selected from a pre-determined PRBS-n sequence, wherein n>1 and M>n. The method includes generating, using a plurality of logic gates of the circuit, a next M-bit word using at least n+1 of the M sequential bits of the initial M-bit word. The method includes repeatedly generating, using the logic gates of the circuit, the next M-bit word from a previous M-bit word using the at least n+1 of M sequential bits of the previous M-bit word, resulting in M parallel sequences of the PRBS-n sequence. The method includes transmitting the generated next M-bit words on an M-bit wide parallel bus.

A random number generator and method for generating random numbers. The random number generator has a noise source configured to generate N sources of N noise bits and has a conditioning component comprising a multiple input exclusive-OR circuit generating feedback bits and a multiple input shift register receiving the feedback bits. The conditioning component is configured to process a sequence of the N noise bits from the N noise sources and output M random bits including the feedback bits obtained as a result of pre-computing.