Fingered electrodes for microfluidic single particle analysis

The electrical properties of particle solutions can be investigated on a single particle basis by using micro fluidic channels. The impedance can be measured across the channel using at least one pair of conductive electrodes, at least one electrode of a pair being a fingered electrode having a plurality of fingers. The pattern of fingered electrodes creates a longer and more complicated measurement signal shape which leads to a significant improvement of measurement sensitivity. An application for the proposed technology is to significantly improve the measurement sensitivity of impedance measurements on blood cells, leading to a better differentiation between different types of white blood cells. Better measurement sensitivity also enables the measurement of smaller particles and higher throughput

Electronic circuit comprising a plurality of processing devices

A computing task, which is to be performed by the electronic circuit, is partitioned into a number of smaller tasks, each smaller task is expressed as one or more commands in the third plurality of commands, which are to be executed by one or more processing devices. The third plurality of commands is produced by a first plurality of dispatchers. The processing devices in the second plurality of processing devices are capable of indicating their availability. The dispatchers do not execute the commands themselves, or at least not all of them. Instead they are dispatched to the second plurality of processing devices. The first plurality of dispatchers typically holds the state of the overall computation. For example, one or more of the first plurality of dispatchers may comprise a memory or a state-machine to hold part or all of the state of the overall computation

Circuit with network of message distributor circuits

Source circuits (10) produce messages that may each be processed by any one of a plurality of processing circuits (14). A network of distributor circuits is provided between the source circuits and the processing circuits (14). Local decisions by the distributor circuits in the network decide for each message to which one of the processing circuits the message will be routed. Messages are supplied to at least two parallel distributor circuits. These distributor circuits (12a) select from further distributor circuits (12b) in the network on the basis of current availability of individual ones of the further distributor circuits (12b). The respective messages are in turn forwarded from the selected further distributor circuits (12b) to data processing circuits (14) along routes selected by the selected further distributor circuits (12b) on the basis of current availability of the data processing circuits (14) and/or subsequent distributor circuits (12c) in the network

Memory architecture

A memory architecture is presented. The memory architecture comprises a first memory and a second memory. The first memory has at least a bank with a first width addressable by a single address. The second memory has a plurality of banks of a second width, said banks being addressable by components of an address vector. The second width is at most half of the first width. The first memory and the second memory are coupled selectively and said first memory and second memory are addressable by an address space. The invention further provides a method for transposing a matrix using the memory architecture comprising following steps. In the first step the matrix elements are moved from the first memory to the second memory. In the second step a set of elements arranged along a warped diagonal of the matrix is loaded into a register. In the fourth step the set of elements stored in the register are rotated until the element originating from the first row of the matrix is in a first location of the register. In the fifth step the rotated set of elements are stored in the second memory to obtain a transposed warped diagonal. The second to fifth steps are repeated with the subsequent warp diagonals until matrix transposition is complete

Method of storing data, method of loading data and signal processor

A method for storing a vector of process data elements (D1, . . . , D8) that have a size of n bits from a register file (RF) into a memory (M) is described. The memory is arranged for storage of a vector of storage data elements in locations (M1, . . . , M5) having a size of m bits, wherein m>n. The method comprises the steps of: exchanging bits (S2) between process data elements in the vector stored in mutually subsequent register elements, the exchanging resulting in a vector of modified data elements (DmI, . . . , Dm8), shuffling (S3) groups of k subsequent bits in the resulting vector, --storing (S4) the resulting shuffled vector of modified data elements as a vector of storage data elements in the memory (M)

Multi-core for mobile phones

High-end mobile phones support multiple radio standards and a rich suite of applications, which involves advanced radio, audio, video, and graphics processing. The overall digital workload amounts to nearly 100GOPS, from 4b integer to 24b floating-point operations. With a power budget of only 1W this inevitably leads to heterogeneous multi-core architectures with aggressive power management. We review the state-of-theart as well as trends

Memory control with selective retention

The present invention relates to a memory circuit and a method of controlling data retention in the memory circuit, wherein a supply signal is selectively switched to a respective one of at least two virtual supply lines (24) each shared by a respective one of a plurality of groups (30-1 to 30-n) of memory cells (C.sub.0,0 to C.sub.y,z). The selective switching is controlled based on a global activity control signal (A), used for setting the memory circuit either into a standby state or into an active state, and a local data retention indication signal (DR1 to DRn) allocated to a dedicated group of memory cells. Thereby, the data retention part of the memory circuit can be adapted to the application and its state, and standby mode leakaged power is only dissipated in those memory cells for which data retentions actually required

Memory control with selective retention

The present invention relates to a memory circuit and a method of controlling data retention in the memory circuit, wherein a supply signal is selectively switched to a respective one of at least two virtual supply lines (24) each shared by a respective one of a plurality of groups (30-1 to 30-n) of memory cells (C.sub.0,0 to C.sub.y,z). The selective switching is controlled based on a global activity control signal (A), used for setting the memory circuit either into a standby state or into an active state, and a local data retention indication signal (DR1 to DRn) allocated to a dedicated group of memory cells. Thereby, the data retention part of the memory circuit can be adapted to the application and its state, and standby mode leakaged power is only dissipated in those memory cells for which data retentions actually required