Civale, J; Rivens, I; Shaw, A; ter Haar, G (2018) Focused ultrasound transducer spatial peak intensity estimation: a comparison of methods. Physics in Medicine and Biology, 63 (5). 055015

Haller, J; Wilkens, V; Shaw, A (2018) Determination of acoustic cavitation probabilities and thresholds using a single focused transducer to induce and detect acoustic cavitation events: I. Method and terminology. Ultrasound in Medicine and Biology, 44 (2). pp. 377-396.

Miloro, P*; Civale, J*; Rivens, I*; Shaw, A (2016) The feasibility of thermal imaging as a future portal imaging device for therapeutic ultrasound. Ultrasound Med. Biol., 42 (8). pp. 2033-2038.

Gelat, P N; Shaw, A (2015) Relationship between acoustic power and acoustic radiation force on absorbing and reflecting targets for spherically focusing radiators. Ultrasound Med. Biol., 41 (3). pp. 832-844.

Shaw, A; ter Haar, G*; Haller, J*; Wilkens, V* (2015) Towards a dosimetric framework for therapeutic ultrasound. Int. J. Hyperthermia, 31 (2). pp. 182-192.

Durando, G*; Guglielmone, C*; Haller, J*; Georg, O*; Shaw, A; Martin, E*; Karaboce, B* (2015) Towards comparison of ultrasound dose measurements - current capabilities and open challenges. Physics Procedia, 70. pp. 1114-1118.

Martin, E M; Shaw, A; Faruqui, N; Shaw, M (2013) Accurate quantification and delivery of thermal dose to cells in culture. J. Acoust. Soc. Am., 134 (5). p. 4182.

Martin, E M; Shaw, A; Faruqui, N; Shaw, M (2013) Accurate quantification and delivery of thermal dose to cells in culture. J. Acoust. Soc. Am., 134 (5). p. 4182.

Khokhlova, V A*; Shmeleva, S M*; Gavrilov, L R*; Martin, E; Sadhoo, N; Shaw, A (2013) Infrared mapping of ultrasound fields generated by medical transducers: feasibility of determining absolute intensity levels. J. Acoust. Soc. Am., 134 (2). pp. 1586-1597.

Shaw, A (2013) Just doing our DUTy! - an international project on dosimetry for ultrasound therapy. J. Acoust. Soc. Am., 134 (5). p. 4152.

Shaw, A (2013) Just doing our DUTy! - an international project on dosimetry for ultrasound therapy. J. Acoust. Soc. Am., 134 (5). p. 4152.

Haller, J*; Jenderka, K V*; Shaw, A; Durando, G*; Karaboce, B* (2012) Metrology of high-intensity therapeutic ultrasound within the EMRP project 'External beam cancer therapy' . Characterization of sources. Metrologia, 49 (5). S267-S270

Haller, J*; Jenderka, K-V*; Shaw, A; Durando, G*; Karaboumice, B* (2012) Metrology of high-intensity therapeutic ultrasound within the EMRP project 'external beam cancer therapy'. Characterization of sources. Metrologia, 49 (5). S267-S270

Gatto, M*; Memoli, G; Shaw, A; Sadhoo, N; Gélat, P N; Harris, R A* (2012) Three-dimensional printing (3DP) of neonatal head phantom for ultrasound: thermocouple embedding and simulation of bone. Med. Eng. Phys., 34 (7). pp. 929-937.

Rajagopal, S; Shaw, A (2012) The buoyancy method - a potential new primary ultrasound power standard. Metrologia, 49 (3). pp. 327-339.

Haller, J*; Jenderka, K V*; Durando, G*; Shaw, A (2012) A comparative evaluation of three hydrophones and a numerical model in high intensity focused ultrasound fields. J. Acoust. Soc. Am., 131 (2). pp. 1121-1130.

Haller, J*; Jenderka, K-V*; Seifert, F*; Klepsch, T*; Martin, E; Shaw, A; Durando, G*; Guglielmone, C*; Girard, F* (2012) A comparison of three different types of temperature measurements in HITU fields. Metrologia, 49 (5). S279-S281

Haller, J*; Jenderka, K-V*; Koch, C*; Seifert, F*; Klepsch, T*; Shaw, A (2012) A low-cost, easy-to-handle calibration phantom for MR thermometry in HIFU fields. AIP Conf. Proc., 1481. pp. 125-130.

Shaw, A; Khokhlova, V*; Bobkova, S*; Gavrilov, L*; Hand, J* (2011) Calibration of HIFU intensity fields measured using an infra-red camera. J. Phys., Conf. Ser., 279. 012019

Karaböce, B*; Gülmez, Y*; Rajagapol, S*; Shaw, A (2011) Instantaneous input electrical power measurement of HITU transducers. J. Phys., Conf. Ser., 279. 012011

Bobkova, S*; Gavrilov, L*; Khokhlova, V*; Shaw, A; Hand, J* (2010) Focusing of high intensity ultrasound through the rib cage using a therapeutic random phased array. Ultrasound Med. Biol., 36 (6). pp. 888-906.

Shaw, A; Nunn, J (2010) The feasibility of an infrared system for real-time visualisation and mapping of ultrasound fields. Phys. Med. Biol., 55 (11). N321-N327

Morris, P*; Hurrell, A*; Shaw, A; Zhang, E*; Beard, P* (2009) A Fabry-Perot fibre optic ultrasonic hydrophone for the simultaneous measurement of temperature and acoustic pressure. J. Acoust. Soc. Am., 125 (6). pp. 3611-3622.

Hand, J W*; Shaw, A; Sadhoo, N; Rajagopol, S*; Dickinson, R J*; Gavrilov, L R* (2009) A random phased array device for delivery of high intensity focused ultrasound. Phys. Med. Biol., 54 (19). pp. 5675-5693.

Hand, J W*; Shaw, A; Sadhoo, N; Rajagopal, S*; Dickinson, R J*; Gavrilov, L R* (2009) A random phased array device for delivery of high intensity focused ultrasound. Phys. Med. Biol., 54 (19). pp. 5675-5693.

Shaw, A; Hodnett, M (2008) Calibration and measurement issues for therapeutic ultrasound. Ultrasonics, 48 (4). pp. 234-252.

Morris, H*; Riven, I*; Shaw, A; ter Haar, G* (2008) Investigation of the viscous heating artefact arising from the use of thermocouples in a focused ultrasound field. Phys. Med. Biol., 53 (17). pp. 4759-4776.

Shaw, A (2008) A buoyancy method for the measurement of total ultrasound power generated by HIFU transducers. Ultrasound Med. Biol., 34 (8). pp. 1327-1342.

Shaw, A; Hekkenberg, R* (2007) Standards to support performance evaluation for diagnostic ultrasound imaging equipment. NPL Report. AC 2

Shaw, A; ter Haar, G* (2006) Requirements for measurement standards in high intensity focused ultrasound (HIFU) fields. NPL Report. DQL-AC 015

Shaw, A; Clemence, M* (2003) MR imaging of temperature rise in ultrasound fields of diagnostic relevance. NPL Report. CAIR 7

Preston, R C; Shaw, A (2001) Recommended ultrasound field safety classification for medical diagnostic devices. Measurement Good Practice Guide. 50

Shaw, A; Pay, N M; Preston, R C; Bond, A D (1999) Proposed standard thermal test object for medical ultrasound. Ultrasound Med. Biol., 25 (1). pp. 121-132.

Shaw, A; Pay, N M; Preston, R C; Bond, A D (1999) A proposed standard thermal test object for medical ultrasound. Ultrasound Med. Biol., 25 (1). pp. 121-132.

Pay, N M; Shaw, A; Bond, A D (1998) Evaluation of potential bone mimicking materials for ultrasound thermal test objects. NPL Report. CMAM 10

Shaw, A; Pay, N M; Preston, R C (1998) Assessment of the likely thermal index values for pulsed Doppler ultrasonic equipment - Stages II and III: experimental assessment of scanner/transducer combinations. NPL Report. CMAM 12

Shaw, A; Pay, N M; Bond, A D; Preston, R C (1998) Temperature rise from pulsed doppler ultrasound. European Journal of Ultrasound, 7 (Suppl.). S13.

Shaw, A; Preston, R C; Bond, A D (1997) Assessment of the likely thermal index values for pulsed Doppler ultrasonic equipment - Stage 1: calculation based on manufacturers' data. NPL Report. CIRA(EXT)018

Beissner, K*; Oosterbaan, W A*; Hekkenberg, R T*; Shaw, A (1996) European intercomparison of ultrasonic power measurements. Acustica - Acta Acust., 82. pp. 450-458.

Shaw, A; Preston, R C; Bacon, D R (1996) Perfusion corrections for ultrasonic heating in non-perfused media. Ultrasound Med. Biol., 22 (2). pp. 203-216.

Shaw, A; Preston, R C (1995) The NPL Ultrasound Beam Calibrator - cost effective measurements to IEC 1157. In: Proc. 1995 World Congress on Ultrasonics, September 1995, Berlin, Germany.

Preston, R C; Shaw, A (1995) That sounds better! Acoustic output - the key to ultrasound instrument accuracy. Qual. Today (Februa). 18 - 21

Shaw, A (1994) Prediction of temperature rise in layered media from measured ultrasonic intensity data. Phys. Med. Biol., 39. 1203 -1218

Shaw, A; Preston, R C (1994) Recent developments in the NPL ultrasound beam calibrator. In: Abstracts of the Institute of Physics Annual Congress, 1994, Brighton.

Bacon, D R; Shaw, A (1993) Experimental validation of predicted temperature rises in tissue-mimicking materials. Phys. Med. Biol., 38 (11). pp. 1647-1659.

Bacon, D R; Shaw, A (1993) Experimental validation of predicted temperature rises in tissue-mimicking materials. Phys. Med. Biol., 38. pp. 1647-1659.