Australia's weather radars

Bureau of Meteorology weather radars
	Radar sites of the network. Indicative radar coverage in 2022. Inner radius (100 km) indicates better coverage. Outer radius (200 km) indicates worse coverage. Note: Does not show coverage degradation from obstructions.
Country of origin	Australia
Manufacturer	Various
No. built	69
Type	C and S bands

Last updated October 19, 2024

The majority of Australia's weather radars are operated by the Bureau of Meteorology (BoM), an executive agency of the Australian Government. The radar network is continually being upgraded with new technology such as doppler and dual polarisation to provide better now-casting. Doppler weather radars are able to detect the movement of precipitation, making it very useful in detecting damaging winds associated with precipitation,^[1] and determining if a thunderstorm has a rotating updraft, a key indicator of the presence of the most dangerous type of thunderstorm, a supercell.^[2]^[3]^[4]

detect debris in the atmosphere, leading to more accurate tornado warnings;^[5]
distinguish between different precipitation types, leading to better estimations of hail size and severity;^[5]
better identify areas of heavy rainfall, leading to more accurate flood warnings;^[6] and
discern between precipitation and non-meteorological echoes such as chaff, birds, and insects.^[5]

The dual polarisation transition

The transition to polarimetric (dual-polarised) radars began in 2017 with the upgrade of 4 Meteor 1500 radars located in Melbourne, Brisbane, Adelaide, and Sydney.^[7] The network has further been enhanced through the installation of 8 new polarimetric Meteor 735 radars across WA,^[8] NSW ^[9] & Victoria,^[10] and two polarimetric WRM200 radars^[11] manufactured by Vaisala, one to replace the radar in Dampier, WA which had been destroyed by severe tropical cyclone Damien in 2020, and one to replace an ageing radar near Gove in the Northern Territory. Six new Meteor 1700s were also installed between 2021 and 2023, 5 located in Qld,^[12] and 1 in Perth, WA,^[8] all equipped with dual polarisation technology. All the radars with the model name 'Meteor' were manufactured by Selex ES, now Leonardo.

Specifications are available for the Meteor 735, Meteor 1700, and the Vaisala WRM200.

Future radar network upgrades

The BoM has plans^[13]^[14]^[15] to:

build a new radar in Tennant Creek;
replace the radar in Townsville ^[16]

Australian Capital Territory

The Australian Capital Territory is served by the Captains Flat radar, located in New South Wales.

New South Wales

Weather radars in New South Wales^[9]^[17]
Name	Location	Elevation (metres)	Model Name	Beamwidth (degrees)	Range Resolution (metres)	IEEE Frequency Band	Doppler	Dual Pol	Rainfall Accumulations	Notes
Brewarrina	29°58′S146°49′E / 29.96°S 146.81°E / -29.96; 146.81	149	Meteor 735	1	250	C	Yes	Yes	Yes
Canberra (Captains Flat)	35°40′S149°31′E / 35.66°S 149.51°E / -35.66; 149.51	1383	DWSR74S14-13	2	250	S	Yes	No	Yes
Grafton	29°37′S152°58′E / 29.62°S 152.97°E / -29.62; 152.97	40	WSR74S-14	2	500	S	No	No	No
Hillston	33°33′S145°31′E / 33.55°S 145.52°E / -33.55; 145.52	144	Meteor 735	1	250	C	Yes	Yes	Yes
Moree	29°30′S149°51′E / 29.50°S 149.85°E / -29.50; 149.85	220	WF100C-8	1.6	500	C	No	No	No
Namoi (Blackjack Mountain)	31°01′26″S150°11′29″E / 31.0240°S 150.1915°E / -31.0240; 150.1915	699	DWSR8502S-14	2	250	S	Yes	No	No
Newcastle	32°43′48″S152°01′37″E / 32.730°S 152.027°E / -32.730; 152.027	84	DWSR74S14-13	2	250	S	Yes	No	Yes
Norfolk Island	29°01′59″S167°55′59″E / 29.033°S 167.933°E / -29.033; 167.933	~120	WF100C-8	1.6		C	No	No	No	The data from this radar is not in the national radar archive and therefore its metadata is inaccessible.
Sydney (Terrey Hills)	33°42′04″S151°12′36″E / 33.701°S 151.210°E / -33.701; 151.210	195	Meteor 1500	1	250	S	Yes	Yes^[7]	Yes
Wagga Wagga	35°10′S147°28′E / 35.17°S 147.47°E / -35.17; 147.47	221	WF100C-8	1.6	500	C	No	No	No
Wollongong (Appin)	34°15′50″S150°52′26″E / 34.264°S 150.874°E / -34.264; 150.874	449	DWSR8502S-14	2	250	S	Yes	No	Yes
Yeoval	32°44′S148°42′E / 32.74°S 148.70°E / -32.74; 148.70	487	Meteor 735	1	250	C	Yes	Yes	Yes	The radar suffers moderate beam obstruction between approximately 70° and 130° due to an area of elevated terrain, meaning there is an underestimation of rain intensity in the lowest radar tilt between the same bearings.
Kurnell	34°00′53″S151°13′34″E / 34.014758°S 151.226227°E / -34.014758; 151.226227	64	WSR81C-12	1	250	C	Yes	No	—	The Kurnell radar is a backup radar and consequently live radar images are not available. Archived radar data is uploaded here

Northern Territory

Weather radars in Northern Territory^[18]^[19]
Name	Location	Elevation (metres)	Model Name	Beamwidth (degrees)	Range Resolution (metres)	IEEE Frequency Band	Doppler	Dual Pol	Rainfall Accumulations	Notes
Alice Springs	23°49′S133°54′E / 23.82°S 133.90°E / -23.82; 133.90	545	WF100C-8	1.6	500	C	No	No	No
Darwin (Berrimah)	12°28′S130°56′E / 12.46°S 130.93°E / -12.46; 130.93	51	Wurrung 2502C	1	250	C	Yes	No	No
Darwin Airport	12°25′29″S130°53′31″E / 12.4247°S 130.8919°E / -12.4247; 130.8919	38	Wurrung 2502C	1.6	250	C	Yes	No	No
Gove	12°17′S136°49′E / 12.28°S 136.82°E / -12.28; 136.82	61	WRM 200	1	250	C	Yes	Yes	No	The WRM200 radar system replaced an aging WF100 radar in July 2023.
Katherine (Tindal)	14°31′S132°27′E / 14.51°S 132.45°E / -14.51; 132.45	131	WSR81C-8	1.6	500	C	No	No	No
Warruwi	11°38′58″S133°22′48″E / 11.6494°S 133.38°E / -11.6494; 133.38	43	Wurrung 2502C	1	250	C	Yes	No	No

Queensland

Weather radars in Queensland^[12]^[20]
Name	Location	Elevation (metres)	Model Name	Beamwidth (degrees)	Range Resolution (metres)	IEEE Frequency Band	Doppler	Dual Pol	Rainfall Accumulations	Notes
Bowen	19°53′S148°05′E / 19.88°S 148.08°E / -19.88; 148.08		WF100C-8	1.6	500	C	No	No	No
Brisbane Airport	27°23′S153°08′E / 27.39°S 153.13°E / -27.39; 153.13		MeteoPress C	1.7	250	C	Yes^[21]	Yes	No	Doppler and dual-polarized measurements aren't available on the BoM website.
Brisbane (Mt Stapylton)	27°43′05″S153°14′24″E / 27.718°S 153.240°E / -27.718; 153.240		Meteor 1500	1	250	S	Yes	Yes ^[7]	Yes
Cairns	16°49′S145°41′E / 16.82°S 145.68°E / -16.82; 145.68		Wurrung 2502C	1	250	C	Yes	No	No	The signal processor was upgraded in August 2023.
Emerald	23°32′58″S148°14′21″E / 23.5494°S 148.2392°E / -23.5494; 148.2392		DWSR 8502	2		S	Yes	No	No
Gladstone	23°52′S151°16′E / 23.86°S 151.26°E / -23.86; 151.26		WSR-74	2		S	No	No	No
Greenvale	18°59′S144°59′E / 18.99°S 144.99°E / -18.99; 144.99		Meteor 1700	1	250	S	Yes	Yes	Yes
Gympie (Mt Kanigan)	25°57′25″S152°34′37″E / 25.957°S 152.577°E / -25.957; 152.577		DWSR 8502	2		S	Yes	No	Yes
Longreach	23°26′S144°17′E / 23.43°S 144.29°E / -23.43; 144.29		WF 100C-8	1.6		C	No	No	No
Mackay	21°07′S149°13′E / 21.12°S 149.22°E / -21.12; 149.22	42	Meteor 1700	1	250	S	Yes	Yes	No	A new radar became operation in December 2023.^[22]
Marburg	27°37′S152°32′E / 27.61°S 152.54°E / -27.61; 152.54	370	Meteor 1700	1	250	S	Yes	Yes	No	In November 2023, a new radar replaced an ageing WSR-74.^[23] The radar suffers beam blockage on the tilts 0.6° and 0.83° to the W and SW of the radar, leading to an under-representation of reflectivity values between those bearings.
Mornington Island	16°40′S139°10′E / 16.67°S 139.17°E / -16.67; 139.17		WF 100C-8	1.6		C	No	No	No
Mount Isa	20°42′41″S139°33′19″E / 20.7114°S 139.5553°E / -20.7114; 139.5553		DWSR 8502	2		S	Yes	No	Yes
Richmond	20°45′S143°08′E / 20.75°S 143.14°E / -20.75; 143.14		Meteor 1700	1	250	S	Yes	Yes^[24]	Yes
Taroom	25°41′46″S149°53′53″E / 25.696°S 149.898°E / -25.696; 149.898		Meteor 1700	1	250	S	Yes	Yes^[25]	Yes
Toowoomba	27°16′27″S151°59′33″E / 27.2743°S 151.9924°E / -27.2743; 151.9924		Meteor 1700	1	250	S	Yes	Yes	No	Installed on the 18th of April 2024
Townsville (Hervey Range)	19°25′S146°33′E / 19.42°S 146.55°E / -19.42; 146.55		DWSR 2502	1		C	Yes	No	No	This radar will be replaced with a new Meteor 1700 radar in 2024.
Warrego	26°26′S147°21′E / 26.44°S 147.35°E / -26.44; 147.35		TVDR 2500	1.6		C	No	No	No
Weipa	12°40′S141°55′E / 12.67°S 141.92°E / -12.67; 141.92		Wurrung 2502C	1		C	Yes	No	No
Willis Island	16°17′17″S149°57′54″E / 16.288°S 149.965°E / -16.288; 149.965		Wurrung 2502C	1.6		C	Yes	No	No

South Australia

Weather radars in South Australia^[26]^[27]
Name	Location	Model Name	Beamwidth (degrees)	Range Resolution (metres)	IEEE Frequency Band	Doppler	Dual Pol	Rainfall Accumulations
Adelaide (Buckland Park)	34°37′01″S138°28′08″E / 34.617°S 138.469°E / -34.617; 138.469	Meteor 1500	1	250	S	Yes	Yes^[7]	Yes
Adelaide (Sellicks Hill)	35°20′S138°30′E / 35.33°S 138.50°E / -35.33; 138.50	WF 100C-8	1.6		C	No	No	Yes
Ceduna	32°08′S133°42′E / 32.13°S 133.70°E / -32.13; 133.70	Wurrung 2502C	1.6		C	Yes	No	Yes
Mt Gambier	37°45′S140°46′E / 37.75°S 140.77°E / -37.75; 140.77	WF 100C-8	1.6		C	No	No	No
Woomera	31°10′S136°48′E / 31.16°S 136.80°E / -31.16; 136.80	WF 100C-8	1.6		C	No	No	No

Tasmania

Weather radars in Tasmania^[28]^[29]
Name	Location	Model Name	Beamwidth (degrees)	IEEE Frequency Band	Doppler	Dual Pol	Rainfall Accumulations
Hobart (Mt Koonya)	43°06′44″S147°48′22″E / 43.1122°S 147.8061°E / -43.1122; 147.8061	Wurrung 2502C	1	C	Yes	No	Yes
Hobart Airport	42°50′S147°31′E / 42.83°S 147.51°E / -42.83; 147.51	WF 100C-6	2	C	No	No	No
N.W. Tasmania (West Takone)	41°10′52″S145°34′44″E / 41.181°S 145.579°E / -41.181; 145.579	Wurrung 2502C	1	C	Yes	No	Yes

Victoria

Weather radar in Victoria^[10]^[30]
Name	Location	Model Name	Beamwidth (degrees)	IEEE Frequency Band	Doppler	Dual Pol	Rainfall Accumulations
Bairnsdale	37°53′S147°34′E / 37.89°S 147.56°E / -37.89; 147.56	Wurrung 2502C	1.6	C	Yes	No	No
Melbourne	37°52′S144°46′E / 37.86°S 144.76°E / -37.86; 144.76	Meteor 1500	1	S	Yes	Yes^[7]	Yes
Melbourne (Broadmeadows)	37°51′19″S144°45′19″E / 37.8553°S 144.7554°E / -37.8553; 144.7554	Wurrung 2502C	1.6	C	Yes	No	Yes
Mildura	34°17′S141°35′E / 34.28°S 141.59°E / -34.28; 141.59	Meteor 735	1	C	Yes	Yes	Yes
Rainbow	35°59′S142°01′E / 35.99°S 142.01°E / -35.99; 142.01	Meteor 735	1	C	Yes	Yes	Yes
Yarrawonga	36°02′S146°02′E / 36.03°S 146.03°E / -36.03; 146.03	WSR 81C	1	C	Yes	No	No

Western Australia

Weather radars in Western Australia^[8]^[31]
Name	Location	Model Name	IEEE Frequency Band	Doppler	Dual Pol	Rainfall Accumulations
Albany	34°56′S117°48′E / 34.94°S 117.80°E / -34.94; 117.80	Meteor 735	C	Yes	Yes	Yes
Broome	17°57′S122°14′E / 17.95°S 122.23°E / -17.95; 122.23	Wurrung 2502C	C	Yes	No	Yes
Carnavon	24°53′S113°40′E / 24.88°S 113.67°E / -24.88; 113.67	DWSR 2502	C	Yes	No	No
Dampier	20°39′S116°41′E / 20.65°S 116.69°E / -20.65; 116.69	WRM 200	C	Yes	Yes^[32]^[11]	Yes
Esperance	33°50′S121°53′E / 33.83°S 121.89°E / -33.83; 121.89	Meteor 735	C	Yes	Yes	Yes
Geraldton	28°48′S114°42′E / 28.80°S 114.70°E / -28.80; 114.70	Meteor 735	C	Yes	Yes	Yes
Giles	25°02′S128°18′E / 25.03°S 128.30°E / -25.03; 128.30	WF 100C-6	C	No	No	No
Halls Creek	18°14′S127°40′E / 18.23°S 127.66°E / -18.23; 127.66	Wurrung 2502C	C	No	No	No
Kalgoorlie	30°47′S121°27′E / 30.79°S 121.45°E / -30.79; 121.45	Wurrung 2502C	C	Yes	No	Yes
Karratha	20°59′S116°53′E / 20.99°S 116.88°E / -20.99; 116.88	Meteor 1700	S	Yes	Yes	No
Learmonth	22°06′S114°00′E / 22.10°S 114.00°E / -22.10; 114.00	TVDR 2500	C	No	No	No
Newdegate	33°05′49″S119°00′32″E / 33.097°S 119.009°E / -33.097; 119.009	Wurrung 2500C	C	Yes	No	Yes
Perth (Serpentine)	32°23′30″S115°52′01″E / 32.391746°S 115.867036°E / -32.391746; 115.867036	Meteor 1700	S	Yes	Yes	Yes
Perth Airport	31°56′S115°59′E / 31.93°S 115.98°E / -31.93; 115.98	Wurrung 2502C	C	No	No	No
Port Hedland	20°22′S118°38′E / 20.37°S 118.63°E / -20.37; 118.63	TVDR 2500	C	No	No	No
South Doodlakine	31°47′S117°57′E / 31.78°S 117.95°E / -31.78; 117.95	Wurrung 2502C	C	Yes	No	Yes
Watheroo	30°22′S116°17′E / 30.36°S 116.29°E / -30.36; 116.29	Wurrung 2502C	C	Yes	No	Yes
Wyndham	15°27′S128°07′E / 15.45°S 128.12°E / -15.45; 128.12	WF 100C-8	C	No	No	No

Research Radars

Note:

Whilst the BoM may/may not own these radars, they are often involved with the radars for research applications.

Research radars^[33]
Name	Location	Elevation	Operational status	Radar model	IEEE Frequency Band	Doppler	Dual Pol	Notes
CPOL	12°14′42″S131°02′42″E / 12.245°S 131.045°E / -12.245; 131.045	50m	Inactive (6/12/1998 - 2/5/2017)	N/A	C	Yes	Yes	The data which CPOL has collected is used to study the microphysical and dynamic properties of thunderstorm convection in Darwin, Australia, enabling the improvement of atmospheric models' representations of the convection formed during the pre-monsoon buildup and active monsoon.^[34]^[35]
CP2	27°40′08″S152°51′46″E / 27.6689°S 152.8627°E / -27.6689; 152.8627	185.5m	Inactive (1/11/2007 - 1/6/2015)	N/A	S & X	Yes	Yes	The CP2 Research radar was a 1970's era radar, which the BoM received as a gift from the NCAR in the United States. The BoM retrofitted it with modern parts which gave it the unique ability to collect data at two frequencies, S and X band. The upgrades also provided state of the art dual polarisation and doppler technologies. The CP in its title stands for cloud physics, and the radar has been used to research thunderstorms, drive improvements in rainfall measurements and hail detection and explore the potential for cloud seeding.^[36]
Ocean Pol	N/A (Mobile radar)	22m	Active (22/3/2015-)	N/A	C	Yes	Yes	This research radar is installed on the RV Investigator, an ocean research vessel. The radar collects data on research voyages, including trips to Antarctic waters, Heard Island and circumnavigations of Australia.^[37]
UQXPOL^[38]	N/A (Mobile radar)	N/A	Active (14/10/2014-)	Furuno WR-2100	X	Yes	Yes	This research radar is operated by the University of Queensland and has been involved with research to improve hail detection and hail size prediction algorithms,^[39] and also with research into bushfires and pyroconvection as part of a $1 million google.org philanthropic venture.^[40]^[41]
Monash University x-band	N/A (Mobile radar)	N/A	Active	Meteor 60DX	X	Yes	Yes

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Project NIMROD was a meteorological field study of severe thunderstorms and their damaging winds conducted by the National Center for Atmospheric Research (NCAR). It took place in the Greater Chicago area from May 15 to June 30, 1978. Data collected was from single cell thunderstorms as well as mesoscale convective systems, such as bow echoes. Using Doppler weather radars and damage clues on the ground, the team studied mesocyclones, downbursts and gust fronts. NIMROD was the first time that microbursts, very localized strong downdrafts under thunderstorms, were detected; this helped improve airport and public safety by the development of systems like the Terminal Doppler Weather Radar and the Low-level windshear alert system.

The 2021–22 Australian region cyclone season, despite a high number of tropical lows forming, was slightly below-average in terms of activity, with ten tropical cyclones forming, two of which intensified further into severe tropical cyclones. The season began from 1 November 2021 and ended on 30 April 2022, but a tropical cyclone could form at any time between 1 July 2021 and 30 June 2022 and would count towards the season total. During the season, tropical cyclones will be officially monitored by one of the three tropical cyclone warning centres (TCWCs) for the region which are operated by the Australian Bureau of Meteorology, National Weather Service of Papua New Guinea and the Indonesian Agency for Meteorology, Climatology and Geophysics. The United States Joint Typhoon Warning Center (JTWC) and other national meteorological services including Météo-France and the Fiji Meteorological Service also monitored the basin during the season.

The 2022–23 Australian region cyclone season was the fourth consecutive season to have below-average activity in terms of named storms. The season officially started on 1 November 2022 and finished on 30 April 2023, however, a tropical cyclone could form at any time between 1 July 2022 and 30 June 2023 and would count towards the season total, as Tropical Cyclone 01U proved in July 26. During the season, tropical cyclones were officially monitored by one of the three tropical cyclone warning centres (TCWCs) for the region which are operated by the Australian Bureau of Meteorology, National Weather Service of Papua New Guinea and the Indonesian Agency for Meteorology, Climatology and Geophysics. The United States Joint Typhoon Warning Center (JTWC) and other national meteorological services including Météo-France and the Fiji Meteorological Service also monitored the basin during the season.

<span class="mw-page-title-main">Dusan S. Zrnic</span> American engineer and weather radar pioneer

Dušan S. Zrnić is an American engineer of Yugoslav origin, head of the Doppler Weather Radar and Remote Sensing Research Group at the National Severe Storms Laboratory (NSSL) as well as assistant professor of electrical engineering and meteorology at the University of Oklahoma in Norman, Oklahoma. His research interests include circuit design, applied mathematics, magnetohydrodynamics, radar signal processing, and systems design.

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