Modelling Miniature Incandescent Light Bulbs for Thermal Infrared ‘THz Torch’ Applications

Hu, Fangjing; Lucyszyn, S.

doi:10.1007/s10762-014-0130-8

Cited by 12 publications

(12 citation statements)

References 22 publications

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“…Moreover, having glass envelopes (e.g. with the miniature COTS incandescent light bulbs used in our earlier proof-of-concept demonstrators), the output radiated power is significantly reduced because of the high absorption of the window glass below ∼65 THz [12]. For these reasons, more efficient but also more expensive miniature COTS thermal emitters can be used.…”

Section: Increased Channel Densitymentioning

confidence: 99%

“…This offers opportunities for developing such systems within this largely unregulated part of the electromagnetic spectrum. The 'THz Torch' concept was recently introduced by the authors for providing secure wireless communications over short distances within the thermal infrared [8][9][10][11][12][13]. Both single-and multi-channel wireless links have been reported; the resilience to interception and jamming with 2.56 kbps frequency division multiplexing (FDM) and 0.64 kbps frequency-hopping spread-spectrum (FHSS) systems has been demonstrated experimentally [11].…”

Section: Introductionmentioning

confidence: 99%

“…Both single-and multi-channel wireless links have been reported; the resilience to interception and jamming with 2.56 kbps frequency division multiplexing (FDM) and 0.64 kbps frequency-hopping spread-spectrum (FHSS) systems has been demonstrated experimentally [11]. Furthermore, the radiation mechanisms for the basic thermal source transducers [12], as well as the power link budget analysis for the system were previously reported [13]. In this paper, we discuss recent advancements in the front-end enabling technologies associated with the THz Torch concept for wireless communications, which go beyond what has already been published.…”

Section: Introductionmentioning

confidence: 99%

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Advances in Front-end Enabling Technologies for Thermal Infrared ‘THz Torch’ Wireless Communications

Lucyszyn

2016

J Infrared Milli Terahz Waves

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The thermal (emitted) infrared frequency bands (typically 20-40 and 60-100 THz) are best known for remote sensing applications that include temperature measurement (e.g. non-contacting thermometers and thermography), night vision and surveillance (e.g. ubiquitous motion sensing and target acquisition). This unregulated part of the electromagnetic spectrum also offers commercial opportunities for the development of short-range secure communications. The 'THz Torch' concept, which fundamentally exploits engineered blackbody radiation by partitioning thermally generated spectral radiance into pre-defined frequency channels, was recently demonstrated by the authors. The thermal radiation within each channel can be independently pulse-modulated, transmitted and detected, to create a robust form of short-range secure communications within the thermal infrared. In this paper, recent progress in the front-end enabling technologies associated with the THz Torch concept is reported. Fundamental limitations of this technology are discussed; possible engineering solutions for further improving the performance of such thermal-based wireless links are proposed and verified either experimentally or through numerical simulations. By exploring a raft of enabling technologies, significant enhancements to both data rate and transmission range can be expected. With good engineering solutions, the THz Torch concept can exploit nineteenth century physics with twentieth century multiplexing schemes for low-cost twenty-first century ubiquitous applications in security and defence.

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Section: Increased Channel Densitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Advances in Front-end Enabling Technologies for Thermal Infrared ‘THz Torch’ Wireless Communications

Lucyszyn

2016

J Infrared Milli Terahz Waves

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“…4. It should be noted that when the total effective radiating areas of A e f f À filament and A e f f À glass are taken into account for the filament and glass envelope, respectively, the resulting radiant intensities are of the same order of magnitude from the two sources of radiation [7]. Furthermore, it is clearly shown that at a bias current of 44 mA, Channel A, C and D are expected to have higher output radiated power, as the spectral radiance peaks locate within the pass bands of their respective filters at this bias point.…”

Section: Transmitter Output Radiant Intensitymentioning

confidence: 99%

“…On the other hand, Channel B is away from either radiation peaks, giving the lowest output radiated power of the four channels, as will be confirmed experimentally in Section 5. [28] and calculated net spectral radiance from both primary and secondary radiation at a bias current of 44 mA [7] 4 Free space losses…”

Section: Transmitter Output Radiant Intensitymentioning

confidence: 99%

Systems Analysis for Thermal Infrared ‘THz Torch’ Applications

Sun

Brindley

et al. 2015

J Infrared Milli Terahz Waves

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The 'THz Torch' concept was recently introduced by the authors for providing secure wireless communications over short distances within the thermal infrared (10-100 THz). Unlike conventional systems, thermal infrared can exploit front-end thermodynamics with engineered blackbody radiation. For the first time, a detailed power link budget analysis is given for this new form of wireless link. The mathematical modeling of a short end-to-end link is provided, which integrates thermodynamics into conventional signal and noise power analysis. As expected from the Friis formula for noise, it is found that the noise contribution from the pyroelectric detector dominates intrinsic noise. From output signal and noise voltage measurements, experimental values for signal-to-noise ratio (SNR) are obtained and compared with calculated predictions. As with conventional communications systems, it is shown for the first time that the measured SNR and measured bit error rate found with this thermodynamics-based system resembles classical empirical models. Our system analysis can serve as an invaluable tool for the development of thermal infrared systems, accurately characterizing each individual channel and, thus, enables the performance of multi-channel 'THz Torch' systems to be optimized.

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Thermodynamics-based Cognitive Demodulation for 'THz Torch' Wireless Communications Links

Ren

Lucyszyn

2020

Sci Rep

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the low-cost 'tHz torch' technology, which exploits the thermal infrared spectrum (ca. 10 to 100 THz), was recently introduced to provide secure low data rate communications links across short distances. in this paper, a thermodynamics-based approach is proposed for greatly enhancing the sensitivity of detection with non-stationary thermal radiation, generated by thermal emitters that have been modulated well beyond their thermal time constants. Here, cognitive demodulation is employed and, unlike all previous demonstrators, allows truly asynchronous operation by dynamically predicting the thermal transients for the next bit to be received. The result is a five-fold increase in the reported operational figure of merit (Range × Bit Rate) for 'THz Torch' wireless communications links. A single-channel (2 m × 125 bps) prototype and an 8-channel frequency-division multiplexed (0.5 m × 1,000 bps) prototype are demonstrated as proof-of-principle exemplars for the enhanced method of demodulation. Measurements show superior bit error rate performance with an increase in range and bit rate, when compared with conventional threshold detection. this work represents a paradigm shift in thermal-based modulation-demodulation of digital data, and offers a practical solution for the implementation of future ubiquitous secure 'THz Torch' wireless communications links; as well as other applications.Wireless links represent the fastest growing area within the digital communications industry. The history of transmitting data wirelessly can be traced back to ancient China, using smoke signaling for long-distance communication. Other early examples of wireless communications include optical telegraphy (Heliography) from the 19th century and photophone in the early 20th century 1 . Today, wireless communications systems play a crucial role in every aspects of human life.In general, wireless communications systems can be found in most parts of the electromagnetic (EM) spectrum; at radio frequencies that extend upwards into the far-infrared (i.e., covering the (sub-)microwave 2 , millimeter-wave 3 and (sub)-terahertz bands 4,5 ) and at optical wavelengths that extend downwards (i.e., across the visible light spectrum 6 into the near-infrared 7 ). However, little research and development has been reported on thermal infrared (i.e., around the near-infrared, having atmospheric transmission windows from 20-40 THz and 60-100 THz) wireless communications links. Until recently, the thermal infrared spectrum has been generally confined to applications that include motion sensing, target acquisition 8 and thermography 9 (e.g., digital thermometers and thermal cameras); having relatively low-cost components that work with incoherent radiation, when compared to extremely expensive components used in coherent systems 10 operating at radio frequencies and optical wavelengths.In 2011, the first thermal infrared wireless communications system 11 was reported, which exploited the use of extremely low-cost thermal emitters (miniature incandescent light ...

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Modelling Miniature Incandescent Light Bulbs for Thermal Infrared ‘THz Torch’ Applications

Cited by 12 publications

References 22 publications

Advances in Front-end Enabling Technologies for Thermal Infrared ‘THz Torch’ Wireless Communications

Advances in Front-end Enabling Technologies for Thermal Infrared ‘THz Torch’ Wireless Communications

Systems Analysis for Thermal Infrared ‘THz Torch’ Applications

Thermodynamics-based Cognitive Demodulation for 'THz Torch' Wireless Communications Links

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