KABI KABI 051552Z 20010KT 10SM CLR 32/19 A2996 RMK AO2 SLP115 T03170194
KACT KACT 051551Z 16007KT 10SM CLR 31/22 A2995 RMK AO2 SLP132 T03110217
KADM KADM 051555Z 17004KT 10SM CLR 31/23 A2993
KADS KADS 051547Z 20010G18KT 10SM SKC 31/21 A2994
KAFW KAFW 051553Z 18010KT 10SM SCT160 BKN300 32/23 A2993 RMK AO2 SLP117 T03170228 $
KBAD KBAD 051556Z AUTO 22005KT 10SM FEW029 31/24 A2997 RMK AO2 SLP150 T03100239
KCNW KCNW 051555Z 16008KT 10SM SKC 30/22 A2995
KCSM KCSM 051553Z 09004KT 10SM CLR 28/19 A2998 RMK AO2 SLP128 T02830194
KDAL KDAL 051553Z 21009KT 10SM FEW030 FEW120 FEW180 SCT250 32/22 A2992 RMK AO2 SLP123 T03220222
KDFW KDFW 051553Z 19009KT 10SM FEW100 SCT250 31/24 A2992 RMK AO2 SLP122 T03110239
KDTN KDTN 051553Z 27006G14KT 10SM SCT026 31/23 A2997 RMK AO2 SLP145 T03060233
KDTO KDTO 051553Z 18012KT 10SM CLR 32/22 A2993 RMK AO2 SLP125 T03170217
KDYS KDYS 051556Z AUTO 17009KT 10SM FEW170 32/17 A2995 RMK AO2 SLP089 T03170168
KFSI KFSI 051556Z AUTO 19005KT 10SM M 29/22 A2994 RMK AO2 SLP130 T02880223 $
KFTW KFTW 051453Z 17010KT 10SM CLR 29/23 A2993 RMK AO2 SLP124 T02890228 53009
KFWS KFWS 051551Z 16006KT 10SM CLR 33/23 A2995
KGGG KGGG 051553Z COR VRB04KT 10SM FEW028 30/22 A2996 RMK AO2 SLP137 T03000222
KGKY KGKY 051553Z 17008KT 10SM CLR 32/22 A2993 RMK AO2 SLP125 T03220222
KGPM KGPM 051550Z 18008KT 10SM SKC 31/22 A2995
KGVT KGVT 051530Z AUTO 19008KT 10SM CLR 32/23 A2995 RMK AO2
KGYI KGYI 051550Z 18009KT 10SM SKC 32/22 A2995
KLAW KLAW 051553Z VRB03KT 10SM CLR 28/20 A2994 RMK AO2 SLP127 T02830200
KLBB KLBB 051553Z 23011KT 10SM FEW150 FEW250 29/17 A3001 RMK AO2 SLP111 T02940167
KLTS KLTS 051556Z AUTO 12005KT 10SM CLR 29/19 A2995 RMK AO2 SLP128 T02890186 $
KMAF KMAF 051553Z 18011KT 9SM CLR 28/18 A3001 RMK AO2 SLP109 T02780178
KMLU KMLU 051553Z 19008KT 10SM CLR 32/23 A2998 RMK AO2 SLP151 T03170228
KNFW KNFW 051552Z 16009KT 10SM FEW100 SCT150 BKN250 32/23 A2993 RMK AO2 SLP120 T03170228 VISNO N $
KOKC KOKC 051552Z 20005KT 10SM R35R/5500VP6000FT FEW250 29/19 A2995 RMK AO2 SLP123 T02940194
KOUN KOUN 051545Z 15007KT 10SM CLR 30/21 A2993
KPWA KPWA 051553Z 22006KT 10SM CLR 30/19 A2994 RMK AO2 SLP119 T03000189
KRBD KRBD 051553Z 17009G16KT 10SM CLR 32/23 A2993 RMK AO2 SLP125 T03170228
KSHV KSHV 051556Z 23008KT 10SM FEW026 SCT280 31/24 A2997 RMK AO2 SLP143 T03060239
KSJT KSJT 051551Z 20011KT 10SM FEW027 29/20 A2996 RMK AO2 SLP117 T02940200
KSPS KSPS 051552Z 18010KT 10SM FEW120 31/22 A2992 RMK AO2 SLP116 T03060217
KTIK KTIK 051556Z AUTO 20006KT 10SM CLR 29/19 A2994 RMK AO2 SLP130 T02930190
KTKI KTKI 051553Z 20009KT 10SM CLR 32/22 A2994 RMK AO2 SLP130 T03170222
KTXK KTXK 051553Z 25007KT 10SM CLR 31/22 A2996 RMK AO2 SLP141 T03060222
KTYR KTYR 051553Z 23007KT 10SM CLR 30/23 A2996 RMK AO2 SLP137 T03000228

NEXRAD Radar For Dallas/Fort Worth
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This is a composite plot of the radar summary, echo tops, storm movement, TVS and MESO signatures and watch boxes. The radar summary is color coded by precip type. Greens, yellows and reds are rain. Pinks are mixed precipitation (freezing rain, sleet). Blues are snow. NOTE: Radar data is susceptible to a phenomena called anomalous propagation. This generally happens at night and appears as a area of 20 dBZ echos (darkest green) which is centered around each radar site and expands with time. To try and reduce the problem, low echo values near the radar sites have been removed.

GOES-16, formerly known as GOES-R before reaching geostationary orbit, is the first of the GOES-R series of Geostationary Operational Environmental Satellite (GOES) operated by NASA and the National Oceanic and Atmospheric Administration (NOAA). GOES-16 serves as the operational geostationary weather satellite in the GOES East position at 75.2°W, providing a view centered on the Americas. GOES-16 provides high spatial and temporal resolution imagery of the Earth through 16 spectral bands at visible and infrared wavelengths using its Advanced Baseline Imager (ABI). GOES-16's Geostationary Lightning Mapper (GLM) is the first operational lightning mapper flown in geostationary orbit. The spacecraft also includes four other scientific instruments for monitoring space weather and the Sun.
The Geostationary Operational Environmental Satellite (GOES) program began as a joint effort between the National Aeronautics and Space Administration (NASA) and the National Oceanic and Atmospheric Administration (NOAA) in 1975 to develop geostationary weather satellites following the success of the Applications Technology Satellite (ATS) and Synchronous Meteorological Satellite programs beginning in 1966. In the 1999 Operational Requirements Document (ORD) for the Evolution of Future NOAA Operational Geostationary Satellites, NOAA listed instrument requirements for the next generation of GOES imager and sounder. Top priorities included continuous observation capabilities, the ability to observe weather phenomena at all spatial scales, and improved spatial and temporal resolution for both the imager and sounder. These specifications laid the conceptual foundations for the instruments that would eventually be included with GOES-16.
Images updated every 5 minutes. NOAA GEOS-16
GOES 16 Visible Radar

The 0.47 micrometer (µm), or “blue” band, one of the two visible bands on the ABI, provides data for monitoring aerosols. The geostationary 0.47 µm band provides nearly continuous daytime observations of dust, haze, smoke and clouds. Measurements of aerosol optical depths (AOD) will help air quality monitoring and tracking, respectively. This blue band, combined with a “green” band and a “red” band (0.64 µm), can provide “simulated natural color” imagery of the Earth. The 0.47 µm band is also useful for air pollution studies and improving numerous products that rely on clear-sky radiances (such as land and sea surface products).
GOES 16 Longwave Infrared

The traditional longwave infrared window (11.2 micrometer (μm)) band enables operational meteorologists to diagnose discrete clouds and organized features for general weather forecasting, analysis, and broadcasting applications. Observations from this infrared window channel can characterize atmospheric processes associated with extratropical cyclones and also in single thunderstorms and convective complexes. The window channel also contributes to many satellite derived products, such as precipitation estimates, cloud-drift winds, hurricane intensity and track analyses, cloud-top heights, volcanic ash detection, as well as fog detection, cloud phase, and cloud particle size estimates.
GOES 16 Shortwave IR 4 Hour Loop

The shortwave IR window (3.9 micrometer (μm)) band (on the current GOES imagers) has been demonstrated to be useful in many applications, including fog/low cloud identification at night, fire/hot-spot identification, volcanic eruption and ash detection, and daytime snow and ice detection. Low-level atmospheric vector winds can also be estimated using this band. The shortwave IR window is also useful for studying urban heat islands and clouds. Compared to nighttime, there will be overall warmer temperatures in this shortwave window band during the day, due to the additional reflected solar component

Surface Data
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This is a composite map contain the following analyses: radar summary (color filled areas), surface data plot (composite station model), frontal locations (in various bold lines) and pressure contours (in thin blue lines).