A 0.35μ CMOS fractional-N transmitter for 315/433/868/915 MHz ISM applications

Int J Infrared Milli Waves

Yang

et al. 2008

Based on the theory of phase-locked loop, the analysis and simulation of direct frequency shift keying to phase-locked oscillator is presented. Then, a W-band digital communication system is developed, in which the millimeter wave phase-locked oscillator of the transmitter is modulated directly by 15grades 2048 kbit/s signal. The results of the experiment in the field show that the phase-locked loop has little influence on the modulating signal. It is a good way to simplify the transmitter configuration and suitable for high bit rate communication.

Section: Introductionmentioning

confidence: 99%

W-band Communication System with Direct Frequency Shift Keying Modulation to Phase-locked Oscillator

Int J Infrared Milli Waves

Yang

et al. 2008

“…This low-voltage requirement brings in an interesting design constraint for the radio. Previously published radio circuits clearly confirm the interest and feasibility of low voltage 6V alkaline cell as the power source implies that the hardware must be compliant with a supply voltage as low as 1V which is the end-of-life voltage of the battery radio blocks such as a 1V CMOS RF receiver-only in [4], a 1V RF transmitter-only in [5] and a 1V transceiver in [6] and [7]. The WiseNET SoC presented here is a fully integrated 1V wireless system-on-a-chip, whose block diagram is illustrated in Figure 1.…”

Section: 1mentioning

confidence: 97%

WiseNET, an Ultra Low-Power RF Transceiver SoC and Communication Protocol Solution for Wireless Sensor Networks

Peiris

Hoiydi

Ribordy

et al.

Analog Circuit Design

Autonomy and size are the most important challenges faced when designing radios for distributed wireless sensor networks (WSN). Reducing power consumption requires optimization across all the layers of the communication stack. The WSN platform developed at CSEM therefore uses a co-design approach that combines WiseMAC, a low-power media access control protocol, with the WiseNET SoC, a complex system-on-chip sensor node to exploit the intimate relationship between the MAC-layer and the radio transceiver parameters. This paper reviews the design and realization of the WiseNET SoC featuring a low-power 1V short-range UHF radio transceiver implemented on a 0.18µm standard digital CMOS process. The WiseNET radio consumes only 2.3mW in receive mode with a sensitivity smaller than −108-dBm at a BER of 10 −3 for 25kb/s FSK in the 433MHz ISM band. The design, simulation and validation of the WiseMAC protocol are also detailed in the context of the deployment of a small ad-hoc network experiment at CSEM, demonstrating that the consumption of the WiseNET solution is more than an order of magnitude lower than a comparable Zigbee-based solution.

A CMOS 434/868 MHz FSK/OOK transmitter with integrated fractional-N PLL

Xiaoping

APCCAS 2008 - 2008 IEEE Asia Pacific Conference on Circuits and Systems

et al. 2008

A 434/868 MHz FSK/OOK transmitter with integrated PLL is reported. Direct digital modulation of a fully integrated ∑-∆ fractional-N PLL frequency synthesizer is used to ensure fine frequency resolution and low phase noise. A wideband VCO together with an Adaptive Frequency Calibration (AFC) is used to cover the desired bands. A differential-to-single output programmable power amplifier is integrated to make the chip low cost and low power. The measurement results show that the phase noise are -76dBc/Hz and -131dBc/Hz at 10-kHz offset and 3-MHz offset with carrier centered at 868 MHz, respectively. The peak output power of the transmitter is 3.5dBm on 50-Ω load and the measured adjacent channel power ratio (ACPR) for 100 kHz channel is less than -50-dBc. The chip is fabricated with 0.35-µm RF CMOS process. The 2-mm 2 transmitter IC including PLL and power amplifier (PA) consumes 87.6mW at 3V voltage supply.I.