diff --git a/antenna.html b/antenna.html index 5560b5fa3834926a2eadc6dddcf8c5e051ef064c..f897a5f9d9dd706f5a300c42ef32a519ae1ea7b2 100644 --- a/antenna.html +++ b/antenna.html @@ -133,7 +133,7 @@ equivalent flux density is the flux density of a radio source that doubles the s <col width="6%" /> <col width="15%" /> <col width="13%" /> -<col width="8%" /> +<col width="9%" /> <col width="9%" /> <col width="10%" /> <col width="9%" /> @@ -156,9 +156,9 @@ equivalent flux density is the flux density of a radio source that doubles the s <td>1</td> <td>linear</td> <td>primary</td> -<td>56.2’</td> +<td>48’</td> <td>[50-80]</td> -<td>[0.45]</td> +<td>[0.52]</td> <td>125</td> </tr> <tr class="row-odd"><td>L</td> @@ -166,9 +166,9 @@ equivalent flux density is the flux density of a radio source that doubles the s <td>1</td> <td>linear</td> <td>primary</td> -<td>12.6’</td> +<td>11.4’</td> <td>25-35</td> -<td>[0.47]</td> +<td>[0.55]</td> <td>36</td> </tr> <tr class="row-even"><td>C-high</td> @@ -176,9 +176,9 @@ equivalent flux density is the flux density of a radio source that doubles the s <td>1</td> <td>circular</td> <td>beam waveguide</td> -<td>2.8’</td> +<td>2.7’</td> <td>32-37(*)</td> -<td>0.48</td> +<td>0.60</td> <td>43(*)</td> </tr> <tr class="row-odd"><td>K</td> @@ -186,9 +186,9 @@ equivalent flux density is the flux density of a radio source that doubles the s <td>7</td> <td>circular</td> <td>Gregorian</td> -<td>50”(**)</td> +<td>0.8’(**)</td> <td>90(**)</td> -<td>0.44</td> +<td>0.45-065</td> <td>138(**)</td> </tr> </tbody> diff --git a/antenna.rst b/antenna.rst index cb134ab39cd777f78116b00f4e0f50a18da6fe45..0faa48adeb8a93d04ad089b701e6ef52aa856a4e 100644 --- a/antenna.rst +++ b/antenna.rst @@ -83,14 +83,14 @@ Receivers In the following table, we outline, for each receiver: its frequency coverage; number of feeds; polarization type; focal position; its beam-size in arcmin or arcsec; measurements of the system temperature Tsys at 45 degrees of elevation; antenna gain; and system equivalent flux density (Sefd) (the system equivalent flux density is the flux density of a radio source that doubles the system temperature). Each receiver feed allows for two polarizations. -======== ========================= ======= ================= =============== ========= ========== =========== ========== -Band Frequency coverage (GHz) Feeds Polarization type Focal position Beam size Tsys (K) Gain (K/Jy) Sefd (Jy) -======== ========================= ======= ================= =============== ========= ========== =========== ========== -P 0.30 -- 0.36 1 linear primary 56.2' [50-80] [0.45] 125 -L 1.3 -- 1.8 1 linear primary 12.6' 25-35 [0.47] 36 -C-high 5.7 -- 7.7 1 circular beam waveguide 2.8' 32-37(*) 0.48 43(*) -K 18 -- 26 7 circular Gregorian 50"(**) 90(**) 0.44 138(**) -======== ========================= ======= ================= =============== ========= ========== =========== ========== +======== ========================= ======= ================= =============== ========== ========== =========== ========== +Band Frequency coverage (GHz) Feeds Polarization type Focal position Beam size Tsys (K) Gain (K/Jy) Sefd (Jy) +======== ========================= ======= ================= =============== ========== ========== =========== ========== +P 0.30 -- 0.36 1 linear primary 48' [50-80] [0.52] 125 +L 1.3 -- 1.8 1 linear primary 11.4' 25-35 [0.55] 36 +C-high 5.7 -- 7.7 1 circular beam waveguide 2.7' 32-37(*) 0.60 43(*) +K 18 -- 26 7 circular Gregorian 0.8'(**) 90(**) 0.45-065 138(**) +======== ========================= ======= ================= =============== ========== ========== =========== ========== [ ] is an estimate (*) at 6.7 GHz