Our customized solutions for your tailored application
NIRSEN solutions are designed and delivered for various projects in the automotive, electronics, machinery, wireless, consumer, smart home, and medical industries.
RF & MM-WAVE IC
57-64-GHz and 77–81-GHz radar sensors, with on-chip FMCW synthesizer based on fractional-N PLL
FMCW transmitter covering 59–71-GHz unlicensed band with output power of +8 dBm and up to 16 fully programmable chirp configurations
60–GHz industrial radar sensor and nFSK transmitter with on-chip PLL and 7–GHz bandwidth
UWB ultra-low power transmitter (IEEE 802.15.4a)
UWB sensor design (3–4 GHz and 7–8 GHz)
Watch based COSPAS/SARSAT beacon IC
UWB (3.1–10.6-GHz) transceiver for professional application
2.4–GHz SiGe high-performance direct I/Q demodulator and modulator
Automotive digital audio broadcasting RF IC
Ka-Band PLLs
AMS IC
Ultra-high sensitive 3D Hall sensor SoC (AMS ICs) for industrial applications
Heat sensor IC
Flowmeter IC
ADC: 2nd & 3rd order SC Sigma-Delta; CT Sigma-Delta; ultra-high-speed GHz sampling in 28-nm CMOS
Integer-N and fractional-N PLLs: from 10 MHz to 81 GHz (with bandwidth up to 11GHz)
Support blocks: bias circuitry, bandgaps, amplifiers, buffers, LDOs, etc
High-voltage automotive design & layout
Digital ASIC & SoC
SoCs with custom CPUs for sensor applications
SoCs with RISC-V platform
Intelligent battery sensor with LIN interface
Hall sensor controller
Power management controller
High-speed multi.channel data loggers
Multi Mbps custom communication protocol for industrial sensor communication, with low latency.
eSi-3250 processor core Designs
Hardware design experience
Custom hardware accelerator – CORDIC
Custom SPI slave with a register bank generator
Synthesis and layout in 130nm
Software design experience
Implementation of different algorithms
Time of Flight, Center of Gravity, Triangulation, CORDIC
Python register bank generator
RISC-V solutions enable powerful and license-free SoC design
The first RISC-V-based radar signal processing accelerator on the market. It brings unprecedented DSP computing power that supports ultra-low latency between target movement and the detection is useful in any real-time operation scenario from automotive to industrial. In addition, this platform allows a real-time visualization of range, range-Doppler, and range-azimuth beamforming and MIMO radar scenes. This feature is crucial for a quick radar prototyping and product development.