Needhelp
?
| 10/100/1000 Ethernet Media Access Controller | By Quotes | None | 125 MHz | 130 nm |  |
|
| The MAC-1G/MAC is a synthesizable HDL core of a high-speed LAN controller. It implements Carrier Sense Multiple Access with Collision Detection (CSMA/CD) algorithms defined by the IEEE 802.3 standard for media access control over the 10Mbps, 100Mbps and 1Gbps Ethernet. Communication with an external host is implemented via a set of Control and Status Registers and the DMA controller for external shared RAM memory. For data transfers the MAC-1G/MAC operates as a DMA master. It automatically fetches from transmit data buffers and stores receive data buffers into external RAM with minimum CPU intervention. The linked list management enables the use of various memory allocation schemes. There is an interface for external dual port RAMs serving as configurable FIFO memories and there are separate memories for transmit and receive processes. Using the FIFOs additionally isolates the MAC-1G/MAC from an external host and provides resolution in case of latency of an external bus. Application Network Interface Cards (NICs) Routers, switching hubs | Introduction | |||||
| 0.13um Real Time Clock | By Quotes | None | 32 KHz | 130 nm | |
|
| The RTC is a 0.13μm Real-Time-Clock cell that provides multiple clocks. This RTC provides an operating voltage range of 2.7V ~ 3.3V, and an operating junction temperature range of -40˚ ~ 125℃. | Introduction | |||||
| 4.2V-to-1.2V DC/DC Converter | By Quotes | 40.000 K μm^2 | 1 MHz | 130 nm | |
|
| The DCDC12 is a 0.13μm DC to DC converter in buck mode cell that converters input voltage to a smaller output voltage. The output voltage can be programmed from 1.05V to 1.3V.An external 10uH inductor is necessary. | Introduction | |||||
| 4.2V-to-1.8V DC/DC Converter | By Quotes | 40.000 K μm^2 | 1 Hz | 130 nm | |
|
| The DCDC18 is a 0.13μm DC to DC converter in buck mode cell that converters input voltage to a smaller output voltage. The output voltage can be programmed from 1.65V to 1.9V.An external 10uH inductor is necessary. | Introduction | |||||
| PLL with Multiple Output Frequency | By Quotes | 40.000 K μm^2 | 12.156 MHz | 130 nm | |
|
| The PLL is a 0.13μm Phase-Locked Loop (PLL) cell that provides a clock multiplier that can generate a stable 48M/96M/120MHz/156MHz clock from a 12MHz clock source. This is a “generic” PLL which integrates the Voltage-Controlled Oscillator (VCO), Phase-Frequency Detector, Low Pass Filter, Loop Divider and Post Divider. This PLL provides an operating voltage range of 1.08V ~ 1.32V, and an operating junction temperature range of -40˚ ~ 125℃. | Introduction | |||||
| 300 mA Capless LDO in 130 nm (VLDS0300LS130) | By Quotes | None | None | 130 nm | |
|
| Power Quencher® Capless LDO (Silicon-proven 130 nm, 300 mA, excellent quiescent current and load transient regulation) The Power Quencher® series of fully-integrated low dropout (LDO) voltage regulators operates with ultra-low levels of power consumption without sacrificing other areas of performance. They achieve a low-noise output voltage and do not require the external output capacitor that is typically needed in an LDO for loop stability and noise reduction. This saves component count, board space and cost, and improves overall system reliability. The Power Quencher® LDO voltage regulator IP cores are optimized for integration into Application Specific Integrated Circuits (ASICs) or Systems-on-a-Chip (SoCs), including radio frequency (RF), wireless, and Internet of Things (IoT) applications. | Introduction | |||||
| Ultra-High Accuracy Bandgap Reference in 130 nm (VBRS1000NT130) | By Quotes | None | None | 130 nm | |
|
| ACCUREF™ Bandgap Reference (Silicon-proven 40 nm, low-power, low-noise, ultra-precise single-digit mV accuracy, no external components required) ACCUREF™ Voltage and Current References: This series of low-power, low-noise IP cores generates a precise, adjustable reference voltage with single-digit millivolt (mV) accuracy over a wide temperature range without external components. With their unique design that improves upon current products by allowing the systems to operate with ultra-low levels of power consumption without sacrificing accuracy or noise performance, our family of ACCUREF™ voltage and current reference IP cores support a broad range of industry applications with improved efficiency and remarkable area savings overall. | Introduction | |||||
| Configurable Reed Solomon Encoder | 30000 Points | 2.500 K Gates | 250 MHz | 180 nm | |
|
| Our IP core implements the Reed Solomon encoding algorithm and is parameterized in terms of bits per symbol, maximum codeword length and maximum number of parity symbols. It also supports varying on the fly shortened codes. Therefore any desirable code-rate can be easily achieved rendering the decoder ideal for fully adaptive FEC applications. ntRSE core supports continuous or burst decoding. The implementation is very low latency, high speed with a simple interface for easy integration in SoC applications. | Introduction | |||||
| AES Codec with 8-bit datapath | 20000 Points | 1.300 K Gates | 515 MHz | 180 nm | |
|
| The IP core implements the NIST FIPS-197 Advanced Encryption Standard and can be programmed to either encrypt or decrypt 128-bit blocks of data using a 128-bit, 192-bit or 256-bit key. The IP has been carefully designed to require minimum logic resources rendering it an ideal solution for low power applications. This has been achieved by using an 8-bit data path size which means that 16 clock cycles are required to load/unload the 128-bit plaintext/ciphertext block. The encryptor receives the 128-bit plaintext block in 8-bit input symbols and generates the corresponding 128-bit ciphertext block in 8-bit output symbols using a supplied 128, 192, or 256-bit AES key. The pre-computed key values are read from an internal round key RAM. A key expander module is provided as an optional module to allow automatic generation and loading of the round key RAM. The decryptor implements the reverse function, generating plaintext from supplied ciphertext, using the same AES key as was used for encryption. The implementation is very low on latency, high speed with a simple interface for easy integration in SoC applications. | Introduction | |||||
| AES Codec with 128-bit datapath | 20000 Points | 22.000 K Gates | 260 MHz | 180 nm | |
|
| The IP core implements the NIST FIPS-197 Advanced Encryption Standard and can be programmed to either encrypt or decrypt 128-bit blocks of data using a 128-bit, 192-bit or 256-bit key. The IP has been carefully designed for high throughput applications with optimal logic resources utilization. The encryptor core accepts a 128-bit plaintext input word, and generates a corresponding 128-bit ciphertext output word using a supplied 128, 192, or 256-bit AES key. The decryptor core provides the reverse function, generating plaintext from supplied ciphertext, using the same AES key as was used for encryption. The hardware roundkey expansion logic has been designed as a discrete building block. This allows either to build a complete stand-alone AES solution, or to save logic resources by leaving the key generation process to the user. Alternatively, the roundkey expansion logic can be shared between multiple encryption/decryption cores for optimal silicon area resources utilization. The implementation is very low on latency, high speed with a simple interface for easy integration in SoC applications. | Introduction | |||||
| μIP | Price | Logic Gate Count | Clock Rate | Technology | Ratings | |
|---|---|---|---|---|---|---|