On the suitability of the 433 MHz band for M2M low‐power wireless communications: propagation aspects

Tuset-Peiró, Pere; Angles-Vazquez, Albert; López-Vicario, José; Vilajosana, Xavier

doi:10.1002/ett.2672

Cited by 30 publications

(19 citation statements)

References 19 publications

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“…At 1m, much like previously experienced at a few meters in the 433MHz band [8], we do not expect that changing frequency would have much effect: accordingly, there is hardly any gain variation above 6dB in the histogram at the top in Figure 2a. However, Figure 2b shows a different behavior: at 1m indoors, gain changes of 6 dB or above are common.…”

Section: Introductionsupporting

confidence: 51%

Why is frequency channel diversity so beneficial in wireless sensor networks?

Varga

Heusse

Guizzetti

et al. 2016

2016 Wireless Days (WD)

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In dense wireless sensor networks, a multichannel MAC is a good means to reduce channel contention and increase frame reception probability. In this paper, we report on experiments with transmissions on various channels in the 2.4GHz ISM band and find more channel diversity than expected: this effect is particularly exacerbated at a short range, but it also has a significant impact at any distance. Moreover, we find that wireless sensor nodes have a radiation pattern that changes significantly with the frequency channel. This feature is inherent to the size of the sensor node, in which the antenna necessarily interferes with other components. The first consequence of this finding is that frequency diversity in sensor networks is even more effective than generally thought, and conversely, single channel communication schemes should be avoided as long as the power budget is not very comfortable.

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Section: Introductionsupporting

confidence: 51%

Why is frequency channel diversity so beneficial in wireless sensor networks?

Varga

Heusse

Guizzetti

et al. 2016

2016 Wireless Days (WD)

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show abstract

“…Another full evaluation kit by Agaidi Oy, Finland, which is no longer available for purchase, is also in circulation. [34] found that 433 MHz was significantly better in free airspace by field tests and theoretical analysis. Our outdoor tests with 433 MHz wireless nodes were conducted with OpenTag running on the Agaidi evaluation kits, based on the CC430F5137 SoC.…”

Section: (B) Alternate Operation Frequencies and Communication Standardsmentioning

confidence: 94%

Communication techniques and challenges for wireless food quality monitoring

Jedermann

Pötsch

Lloyd

2014

Phil. Trans. R. Soc. A.

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Remote measurement of product core temperature is an important prerequisite to improve the cool chain of food products and reduce losses. This paper examines and shows possible solutions to technical challenges that still hinder practical applications of wireless sensor networks in the field of food transport supervision. The high signal attenuation by water-containing products limits the communication range to less than 0.5 m for the commonly used 2.4 GHz radio chips. By theoretical analysis of the dependency of signal attenuation on the operating frequency, we show that the signal attenuation can be largely reduced by the use of 433 MHz or 866 MHz devices, but forwarding of messages over multiple hops inside a sensor network is mostly unavoidable to guarantee full coverage of a packed container. Communication protocols have to provide compatibility with widely accepted standards for integration into the global Internet, which has been achieved by programming an implementation of the constrained application protocol for wireless sensor nodes and integrating into IPv6-based networks. The sensor's battery lifetime can be extended by optimizing communication protocols and by in-network pre-processing of the sensor data. The feasibility of remote freight supervision was demonstrated by our full-scale ‘Intelligent Container’ prototype.

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“…This is due to the fact that the channel coherence bandwidth at the sub-GHz bands is larger than the available bandwidth [33], which causes that all the channels of the band are highly correlated. Taking into consideration these results, other mechanisms may be required to add robustness against multi-path propagation in LPDQ implementations that operate at Sub-GHz bands.…”

Section: Multi-path Propagationmentioning

confidence: 99%

“…For our implementation, we have used a data rate of 250 kbps, which yields a measured sensitivity of -91 dBm for a PER (Packet Error Rate) of 1% transmitting packets of 20 bytes and using a channel bandwidth of 540 kHz. This data rate has been selected because it is equivalent to that of IEEE 802.15.4 and achieves the least energy consumption per bit while offering a range that has been measured to be 1.6 times that of the 2.4 GHz band in real conditions [33]. In case that a longer range is required, the lower data rates defined in the standard, e.g., 31 kbps or 100 kbps, can be selected at the expense of increasing the energy consumption per bit if the transmit power is kept constant.…”

Section: Physical Layermentioning

confidence: 99%