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36 |
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37 | \title{Neuantrag auf Gew\"{a}hrung einer Sachbeihilfe\\Proposal for a new research project}
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38 | \author{Prof.\ Dr.\ Karl\ Mannheim\\Prof.\ Dr.\ Dr.\ Wolfgang Rhode}
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39 |
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40 | \begin{document}
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41 |
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42 | \maketitle
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43 | \newpage
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44 | \mbox{}
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45 | \thispagestyle{empty}
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46 | \cleardoublepage
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47 | \newpage
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48 |
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49 | \section[1]{General Information (Allgemeine Angaben)}
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50 |
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51 | \subsection[1.1]{Applicants (Antragsteller)}
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52 | \germanTeX
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53 | \begin{tabular}{|p{0.44\textwidth}|p{0.22\textwidth}|p{0.22\textwidth}|}\hline
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54 | {\bf Name}&\multicolumn{2}{l|}{\bf Akademischer Grad}\\
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55 | {\sc Rhode, Wolfgang, Prof.~Dr.~Dr.}&\multicolumn{2}{l|}{Universit"atsprofessor (C3)}\\\hline\hline
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56 | {\ }&{\bf Birthday}&{\bf Nationality}\\
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57 | {\ }&Oct 17 1961&German\\\hline
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58 | \multicolumn{3}{|l|}{\bf Institut, Lehrstuhl}\\
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59 | \multicolumn{3}{|l|}{Institut f"ur Physik}\\
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60 | \multicolumn{3}{|l|}{Experimentelle Physik V (Astroteilchenphysik)}\\\hline
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61 | {\bf Address at work }&\multicolumn{2}{l|}{\bf Home address}\\[0.5ex]
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62 | {Universit"at Dortmund }&\multicolumn{2}{l|}{ }\\
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63 | { }&\multicolumn{2}{l|}{Am Schilken 28 }\\
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64 | {44221 Dortmund }&\multicolumn{2}{l|}{58285 Gevelsberg}\\
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65 | {Germany }&\multicolumn{2}{l|}{Germany }\\[0.5ex]
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66 | {\parbox[t]{1.5cm}{Phone:}+49\,(231)\,755-3550}&\multicolumn{2}{l|}{\parbox[t]{1.5cm}{Phone:}+49\,(173)\,284\,79\,10}\\
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67 | {\parbox[t]{1.5cm}{Fax:}+49\,(231)\,755-4547}&\multicolumn{2}{l|}{~}\\\hline\hline
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68 | \multicolumn{3}{|c|}{{\bf email}: wolfgang.rhode@udo.edu}\\\hline
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69 |
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70 | \multicolumn{3}{c}{~}\\[1ex]\hline
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71 |
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72 | {\bf Name}&\multicolumn{2}{l|}{\bf Akademischer Grad}\\
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73 | {\sc Mannheim, Karl, Prof.~Dr.}&\multicolumn{2}{l|}{Universit"atsprofessor (C4)}\\\hline\hline
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74 | {\ }&{\bf Birthday}&{\bf Nationality}\\
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75 | {\ }&Jan 4 1963&German\\\hline
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76 | \multicolumn{3}{|l|}{\bf Institut, Lehrstuhl}\\
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77 | \multicolumn{3}{|l|}{Institut f"ur Theoretische Physik und Astrophysik}\\
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78 | \multicolumn{3}{|l|}{Lehrstuhl f"ur Astronomie}\\\hline
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79 | {\bf Address at work }&\multicolumn{2}{l|}{\bf Home address}\\[0.5ex]
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80 | {Julius-Maximilians-Universit"at}&\multicolumn{2}{l|}{ }\\
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81 | { }&\multicolumn{2}{l|}{Oswald-Kunzemann-Str. 12}\\
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82 | {97074 W"urzburg }&\multicolumn{2}{l|}{97299 Zell am Main }\\
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83 | {Germany }&\multicolumn{2}{l|}{Germany }\\[0.5ex]
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84 | {\parbox[t]{1.5cm}{Phone:}+49\,(931)\,888-5031}&\multicolumn{2}{l|}{\parbox[t]{1.5cm}{Phone: +49\,(931)\,404\,81\,90} }\\
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85 | {\parbox[t]{1.5cm}{Fax:}+49\,(931)\,888-4603}&\multicolumn{2}{l|}{~}\\\hline\hline
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86 | \multicolumn{3}{|c|}{{\bf email}: mannheim@astro.uni-wuerzbueg.de}\\\hline
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87 | \end{tabular}
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88 | \originalTeX
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89 | \newpage
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90 |
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91 | \paragraph{1.2 Topic}~\\
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92 | %\subsection[1.2]{Topic}
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93 | Long-term VHE $\gamma$-ray monitoring of bright blazars with a dedicated Cherenkov telescope
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94 |
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95 | \paragraph{1.2 Thema}~\\
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96 | %\subsection[1.2]{Thema}
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97 | Langzeitbeobachtung von hellen VHE $\gamma$-Blazaren mit einem dedizierten Cherenkov Teleskop
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98 |
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99 | \paragraph{1.3 Discipline and field of work (Fachgebiet und Arbeitsrichtung)}~\\
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100 | %\subsection[1.3]{Discipline and field of work (Fachgebiet und Arbeitsrichtung)}
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101 | Astronomy and Astrophysics, Particle Astrophysics
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102 |
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103 | \paragraph{\bf 1.4 Scheduled duration in total (Voraussichtliche Gesamtdauer)}~\\
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104 | %\subsection[1.4]{Scheduled duration in total (Voraussichtliche Gesamtdauer)}
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105 | After successful completion of the three-year work plan developed in
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106 | this proposal, we will ask for an extension of the project for another
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107 | two years to carry out an observation program centered on the signatures
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108 | of supermassive binary black holes.
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109 |
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110 | \paragraph{\bf 1.5 Application period (Antragszeitraum)}~\\
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111 | %\subsection[1.5]{Application period (Antragszeitraum)}
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112 | 3\,years. The work on the project will begin immediately after the
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113 | funding.
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114 |
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115 | \newpage
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116 | \paragraph{\bf 1.6 Summary}~\\
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117 | %\subsection[1.6]{Summary}
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118 | We propose to set up a robotic imaging air-Cherenkov telescope with low
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119 | cost, but a high performance design for remote operation. The goal is
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120 | the long-term monitoring observations of nearby, bright blazars at very
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121 | high energies. We will (i) search for orbital modulation of the blazar
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122 | emission due to supermassive black hole binaries, (ii) study the
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123 | statistics of flares and their physical origin, and (iii) correlate the
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124 | data with corresponding data from the neutrino observatory IceCube to
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125 | search for evidence of hadronic emission processes. The observations
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126 | will furthermore trigger follow-up observations of flares with higher
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127 | sensitivity telescopes such as MAGIC, \mbox{VERITAS} and H.E.S.S. Joint
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128 | observations with the Whipple monitoring telescope will start a future
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129 | \mbox{24\,h-monitoring} of selected sources with a distributed network of
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130 | robotic telescopes. The telescope design is based on a complete
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131 | technological upgrade of one of the former telescopes of the HEGRA
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132 | collaboration (CT3) still located at the Observatorio del Roque de los
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133 | Muchachos on the Canary Island La Palma (Spain). After this upgrade,
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134 | the telescope will be operated robotically, a much lower energy
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135 | threshold below 350\,GeV will be achieved, and the observation time
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136 | required for gaining the same signal as with CT3 will be reduced by a
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137 | factor of six.
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138 |
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139 | \germanTeX
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140 | \paragraph{\bf 1.6 Zusammenfassung}~\\
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141 | %\subsection[1.6]{Zusammenfassung}
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142 | Das Ziel unseres Vorhabens ist es, ein abbildendes
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143 | Luft-Cherenkov-Teleskop mit geringen Kosten, aber hoher Leistung f"ur
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144 | den ferngesteuerten Betrieb aufzubauen. Die Motivation ist die
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145 | kontinuierliche Langzeitbeobachtung von hellen, nahen Blazaren bei sehr
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146 | hohen Energien. Mit diesen Beobachtungen werden wir nach
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147 | bahndynamischen Modulationen suchen, welche von Bin"arsystemen
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148 | supermassiver schwarzer L"ocher in der emittierten Strahlung
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149 | hervorgerufen werden. Au"serdem werden die gewonnenen Daten mit den
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150 | entsprechenden Daten des Neutrinoteleskops IceCube korreliert, um nach
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151 | Hinweisen f"ur hadroninduzierte Emissionsprozesse zu suchen. Die
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152 | kontinuierliche "Uberwachung ausgew"ahlter Quellen wird zudem besser
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153 | aufgel"oste Beobachtungen und Nachbeobachtungen von
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154 | Strahlungsausbr"uchen durch Teleskope h"oherer Sensitivit"at, wie z.B.\
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155 | MAGIC, VERITAS und H.E.S.S., erlauben. Die zeitversetzten, gemeinsamen
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156 | Beobachtungen zusammen mit dem Whipple-Teleskop stellen den Beginn
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157 | ununterbrochener Beobachtungen mit einem weltweiten Netzwerk
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158 | robotischer Teleskope dar. Unser Teleskopdesign basiert auf einer
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159 | technischen Runderneuerung eines Teleskops der fr"uheren
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160 | HEGRA-Kollaboration (CT3), welches noch immer am Observatorio del Roque de
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161 | los Muchachos auf der Kanarischen Insel La Palma (Spanien) steht. Nach
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162 | dieser Aufr"ustung wird das Teleskop vollst"andig ferngesteuert
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163 | betrieben werden, eine viel niedrigere Energieschwelle von unter
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164 | 350\,GeV erreichen und die Beobachtungszeit, um ein gleichstarkes
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165 | Signal wie mit CT3 zu erhalten, wird um einen Faktor sechs k"urzer
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166 | sein.
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167 | \originalTeX
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168 | \newpage
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169 |
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170 | \section[2]{Science case, preliminary work by proposer\\(Stand der Forschung, eigene Vorarbeiten)}
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171 |
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172 | \subsection[2.1]{Science case (Stand der Forschung)}
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173 |
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174 | Since the termination of the HEGRA observations, the succeeding
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175 | experiments MAGIC and H.E.S.S.\ have impressively extended the physical
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176 | scope of gamma-ray astronomy detecting tens of formerly unknown gamma-ray
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177 | sources and analyzing their energy spectra, morphology and
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178 | temporal behavior. This became possible by lowering the energy
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179 | threshold from 700\,GeV to less than 100\,GeV and increasing at the same
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180 | time the sensitivity by a factor of five. A diversity of astrophysical
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181 | source types such as pulsar wind nebulae, supernova remnants,
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182 | micro-quasars, pulsars, radio galaxies, clusters of galaxies, Gamma-Ray
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183 | Bursts and blazars have been studied with these telescopes.
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184 |
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185 | The main class of extragalactic, very high energy gamma-rays sources
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186 | detected with imaging air-Cherenkov telescopes are blazars, i.e.\
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187 | accreting supermassive black holes exhibiting a relativistic jet that
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188 | is closely aligned with the line of sight. The non-thermal blazar
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189 | spectrum covers up to 20 orders of magnitude in energy, from
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190 | long-wavelength radio waves to multi-TeV gamma-rays. In addition,
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191 | blazars are characterized by rapid variability, high degrees of
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192 | polarization, and superluminal motion of knots in their
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193 | high-resolution radio images. The observed behavior can readily be
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194 | explained assuming relativistic bulk motion and in situ particle
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195 | acceleration, e.g.\ at shock waves, leading to synchrotron
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196 | (radio-to-x-ray) and self-Compton (gamma-ray) emission \citep{Blandford}.
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197 | Additionally, inverse Compton scattering of external photons may play a
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198 | role in producing the observed gamma-rays \citep{Dermer,Begelman}.
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199 | Variability may hold the key to understanding the details of the
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200 | emission processes and the source geometry. The development of
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201 | time-dependent models is currently under investigation
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202 | worldwide.
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203 |
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204 | Although particle acceleration inevitably affects electrons and protons
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205 | (ions), the electrons are commonly believed to be responsible for
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206 | producing the observed emission owing to their lower mass and thus much
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207 | stronger energy losses (at the same energy). The relativistic protons,
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208 | which could either originate from the accretion flow or from entrained
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209 | ambient matter, will quickly dominate the momentum flow of the jet.
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210 | This {\em baryon pollution} has been suggested to solve the energy
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211 | transport problem in Gamma-Ray Bursts and is probably present in
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212 | blazar jets as well, even if they originate as pair jets in a black
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213 | hole ergosphere \citep{Meszaros}. Protons and ions accelerated in the
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214 | jets of blazars can reach extremely high energies, before energy losses
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215 | become important \citep{Mannheim:1993}. Escaping particles contribute
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216 | to the observed flux of ultrahigh energy cosmic rays in a major way.
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217 | Blazars and their unbeamed hosts, the radio galaxies, are thus the
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218 | prime candidates for origin of ultrahigh energy cosmic rays
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219 | \citep{Rachen}. This can be investigated with the IceCube and AUGER
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220 | experiments. Recent results of the AUGER experiment show a significant
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221 | anisotropy of the highest energy cosmic rays and point at either nearby
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222 | AGN or sources with a similar spacial distribution as their origin
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223 | \citep{AUGER-AGN}.
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224 |
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225 | In some flares, a large ratio of the gamma-ray to optical luminosity is
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226 | observed. This is difficult to reconcile with the primary leptonic
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227 | origin of the emission, since the accelerated electron pressure would
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228 | largely exceed the magnetic field pressure. For shock acceleration to
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229 | work efficiently, particles must be confined by the magnetic field for
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230 | a time longer than the cooling time. The problem vanishes in the
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231 | following model: Photo-hadronic interactions of accelerated protons and
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232 | synchrotron photons induce electromagnetic cascades, which in turn
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233 | produce secondary electrons causing high energy synchrotron
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234 | gamma-radiation. This demands much stronger magnetic fields in line
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235 | with magnetic confinement \citep{Mannheim:1995}. Short variability time
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236 | scales can result from dynamical changes of the emission zone, running
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237 | e.g.\ through an inhomogeneous environment.
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238 |
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239 | The contemporaneous spectral energy distributions for hadronic and
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240 | leptonic models bear many similarities, but also marked differences,
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241 | such as multiple bumps which are possible even in a one-zone hadronic
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242 | model \citep{Mannheim:1999}. These properties allow conclusions
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243 | about the accelerated particles. Noteworthy, even for nearby blazars
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244 | the spectrum must be corrected for attenuation of the gamma-rays due to
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245 | pair production in collisions with low-energy photons from the
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246 | extragalactic background radiation field \citep{Kneiske}.
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247 | Ultimately, the hadronic origin of the emission must be probed with
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248 | correlated gamma-ray and neutrino observations, since the pion decay
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249 | initiating the cascades involves a fixed ratio of electron-positron
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250 | pairs, gamma-rays, and neutrinos. A dedicated monitoring campaign
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251 | jointly with IceCube has the best chance for success. Pilot studies
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252 | done with MAGIC and IceCube indicate that the investigation of neutrino
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253 | event triggered gamma-ray observations are statistically
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254 | inconclusive \citep{Leier:2006}.
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255 |
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256 | The variability time scale of blazars ranges from minutes to months,
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257 | generally showing the largest amplitudes and the shortest time scales
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258 | at the highest energies. Recently, a doubling time scale of two minutes
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259 | has been observed in a flare of Mrk\,501 with the MAGIC telescope
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260 | \citep{Albert:501}. A giant flare of PKS\,2155-304 discovered by
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261 | H.E.S.S.\ \citep{Aharonian:2007pks} has shown similarly short doubling
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262 | time scales and a flux of up to 16 times the flux of the Crab Nebula.
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263 | Indications for TeV flares without evidence for an accompanying x-ray
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264 | flare, coined orphan flares, have been observed, questioning the
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265 | synchrotron-self-Compton mechanism being responsible for the
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266 | gamma-rays. Model ramifications involving several emission components,
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267 | external seed photons, or hadronically induced emission may solve the
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268 | problem \citep{Blazejowski}. Certainly, the database for
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269 | contemporaneous multi-wavelength observations is still far from proving
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270 | the synchrotron-self-Compton model.
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271 |
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272 | Generally, observations of flares are prompted by optical or x-ray
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273 | alerts, leading to a strong selection bias. The variability presumably
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274 | reflects the non-steady feeding of the jets and the changing interplay
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275 | between particle acceleration and cooling. In this situation,
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276 | perturbations of the electron density or the bulk plasma velocity are
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277 | traveling down the jet. The variability could also reflect the changing
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278 | conditions of the external medium to which the jet flow adapts during
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279 | its passage through it. In fact, a clumpy, highly inhomogeneous
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280 | external medium is typical for active galactic nuclei, as indicated by
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281 | their clumpy emission line regions, if visible against the
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282 | Doppler-enhanced blazar emission. Often the jets bend with a large
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283 | angle indicating shocks resulting from reflections off intervening
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284 | high-density clouds. Changes in the direction of the jet flow lead to
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285 | large flux variations due to differential Doppler boosting.
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286 |
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287 | Helical trajectories, as seen in high-resolution radio maps resulting
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288 | from the orbital modulation of the jet base in supermassive black hole
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289 | binaries, would lead to periodic variability on time scales of months
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290 | to years \citep{Rieger:2007}. Binaries are expected to be the most
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291 | common outcome of the repeated mergers of galaxies which have
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292 | originally built up the blazar host galaxy. Each progenitor galaxy
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293 | brings its own supermassive black hole as expected from the
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294 | Magorrian-Kormendy relations. It is subject to stellar dynamical
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295 | evolution in the core of the merger galaxy, of which only one pair of
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296 | black holes is expected to survive near the center of gravity.
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297 | Supermassive black hole binaries close to coalescence are thus expected
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298 | to be generic in blazars. Angular momentum transport by collective
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299 | stellar dynamical processes is efficient to bring them to distances
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300 | close to where the emission of gravitational waves begins to dominate
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301 | their further evolution until coalescence. Their expected gravitational
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302 | wave luminosity is spectacularly high, even long before final
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303 | coalescence and the frequencies are favorable for the detectors under
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304 | consideration (LISA). The detection of gravitational waves relies on exact
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305 | templates to filter out the signals and the templates can be computed
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306 | from astrophysical constraints on the orbits and masses of the black
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307 | holes. TeV gamma-rays, showing the shortest variability time scales,
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308 | probe deepest into the jet and are thus the most sensitive probe of the
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309 | orbital modulation at the jet base. Relativistic aberration is helpful
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310 | in bringing down the observed periods to below the time scale of years.
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311 | A tentative hint for a 23-day periodicity of the TeV emission from
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312 | Mrk\,501 during a phase of high activity in 1997 was reported by
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313 | HEGRA \citep{Kranich}, and was later confirmed including x-ray and
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314 | Telescope Array data \citep{Osone}. The observations can be explained in
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315 | a supermassive black hole binary scenario \citep{Rieger:2000}.
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316 | Indications for helical trajectories and periodic modulation of optical
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317 | and radio lightcurves on time scales of tens of years have also been
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318 | described in the literature (e.g. \cite{Hong,Merrit}).
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319 |
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320 | To overcome the limitations of biased sampling, a complete monitoring
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321 | database for a few representative bright sources needs to be obtained.
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322 | Space missions with all-sky observations at lower photon energies, such
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323 | as GLAST, GRIPS, or eROSITA, will provide significant multi-wavelength
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324 | exposure simultaneous to the VHE observations, and this is a new
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325 | qualitative step for blazar research. For the same reasons, the VERITAS
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326 | collaboration keeps the Whipple telescope alive, albeit its
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327 | performance seems to have strongly degraded. It is obvious that the
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328 | large Cherenkov telescopes such as MAGIC, H.E.S.S.\ or VERITAS are mainly
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329 | used to discover new sources at the sensitivity limit. Thus they will
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330 | not perform monitoring observations of bright sources with complete
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331 | sampling during their visibility. However, these telescopes will be
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332 | triggered by monitoring telescopes and thus improve the described
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333 | investigations. In turn, operating a smaller but robotic telescope is
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334 | an essential and cost-effective contribution to the plans for
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335 | next-generation instruments in ground-based gamma-ray astronomy.
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336 | Know-how for the operation of future networks of robotic Cherenkov
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337 | telescopes, e.g. a monitoring array around the globe or a single-place
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338 | array like CTA, is certainly needed given the high operating shift
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339 | demands of the current installations.
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340 |
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341 | In summary, there are strong reasons to make an effort for the
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342 | continuous monitoring of the few exceptionally bright blazars. This can
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343 | be achieved by operating a dedicated monitoring telescope of the
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344 | HEGRA-type, referred to in the following as DWARF (Dedicated
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345 | multiWavelength Agn Research Facility). Its robotic design will keep
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346 | the demands on personal and infrastructure on the low side, rendering
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347 | it compatible with the resources of University groups. The approach is
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348 | also optimal to educate students in the strongly expanding field of
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349 | astroparticle physics.
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350 |
|
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351 | Assuming conservatively the performance of a single HEGRA-type
|
---|
352 | telescope, long-term monitor\-ing of at least the following known
|
---|
353 | blazars is possible: Mrk\,421, Mrk\,501, 1ES\,2344+514, 1ES\,1959+650,
|
---|
354 | H\,1426+428, PKS\,2155-304. We emphasize, that DWARF will run as a
|
---|
355 | facility dedicated to these targets only, providing a maximum
|
---|
356 | observation time for the program. Utilizing recent developments, such
|
---|
357 | as improvements of the light collection efficiency due to an improved
|
---|
358 | mirror reflectivity and a better PM quantum efficiency, a 30\%
|
---|
359 | improvement in sensitivity and a lower energy-threshold is reasonable.
|
---|
360 | Current studies show that with a good timing resolution (2\,GHz) a
|
---|
361 | further 40\% increase in sensitivity (compared to a 300\,MHz system) is
|
---|
362 | feasible. Together with an extended mirror area and a large camera, a
|
---|
363 | sensitivity improvement compared to a single HEGRA telescope of a
|
---|
364 | factor of 2.5 and an energy threshold below 350\,GeV is possible.
|
---|
365 |
|
---|
366 | \subsection[2.2]{Preliminary work by proposers (Eigene Vorarbeiten)}
|
---|
367 |
|
---|
368 | From the experience with the construction, operation and data analysis
|
---|
369 | of Amanda, IceCube, HEGRA and MAGIC the proposing groups contribute the
|
---|
370 | necessary knowledge and experience to build and operate a small imaging
|
---|
371 | air-Cherenkov telescope.
|
---|
372 |
|
---|
373 | \paragraph{Hardware}
|
---|
374 |
|
---|
375 | The Dortmund group is working on experimental and phenomenological
|
---|
376 | astroparticle physics. In the past, the following hardware components
|
---|
377 | were successfully developed: a Flash-ADC based DAQ (TWR, transient
|
---|
378 | waveform recorder), currently in operation for data acquisition in the
|
---|
379 | AMANDA subdetector within the IceCube telescope \citep{Wagner:PhD}, an
|
---|
380 | online software Trigger for the TWR-DAQ system \citep{Messarius:PhD},
|
---|
381 | online data compression mechanisms (TWR DAQ) \citep{Refflinghaus:Dipl},
|
---|
382 | monitoring software for the TWR-DAQ-data \citep{Dreyer:Dipl} and
|
---|
383 | in-ice-HV-power-supply for IceCube. This development was done with the
|
---|
384 | companies CAEN, Pisa, Italy and Iseg, Rossendorf, Germany. The HV
|
---|
385 | modules were long time tested under different temperature conditions
|
---|
386 | connected to operating photomultipliers \citep{Bartelt:Dipl}. Prototypes
|
---|
387 | for the scintillator counters of the planned Air Shower Array {\em
|
---|
388 | SkyView} were developed and operated for two years \citep{Deeg:Dipl}.
|
---|
389 | Members of the group (engineers) were involved in the fast trigger
|
---|
390 | development for H1 and are involved in the FPGA-programming for the
|
---|
391 | LHCb data read out. The group may further use the well equipped
|
---|
392 | mechanical and electronic workshops in Dortmund and the electronic
|
---|
393 | development departure of the faculty.
|
---|
394 |
|
---|
395 | The ultra fast drive system of the MAGIC telescopes, suitable for fast
|
---|
396 | repositioning in case of Gamma-Ray Bursts, has been developed,
|
---|
397 | commissioned and programmed by the W\"{u}rzburg group
|
---|
398 | \citep{Bretz:2003drive,Bretz:2005drive}. To correct for axis
|
---|
399 | misalignments and possible deformations of the structure (e.g.\ bending
|
---|
400 | of camera holding masts), a pointing correction algorithm was developed
|
---|
401 | \citep{Dorner:Diploma}. Its calibration is done by measurement of the
|
---|
402 | reflection of bright guide stars on the camera surface and ensures a
|
---|
403 | pointing accuracy well below the pixel diameter. Hardware and software
|
---|
404 | (CCD readout, image processing and pointing correction algorithms) have
|
---|
405 | also been developed and are in operation successfully since more than
|
---|
406 | three years \citep{Riegel:2005icrc2}.
|
---|
407 |
|
---|
408 | Mirror structures made of plastic material have been developed as
|
---|
409 | Winston cones for balloon flight experiments previously by the group of
|
---|
410 | Wolfgang Dr\"{o}ge. W\"{u}rzburg has also participated in the development of
|
---|
411 | a HPD test bench, which has been setup in Munich and W\"{u}rzburg. With
|
---|
412 | this setup, HPDs for future improvement of the sensitivity of the MAGIC
|
---|
413 | camera are investigated.
|
---|
414 |
|
---|
415 | \paragraph{Software}
|
---|
416 |
|
---|
417 | The W\"{u}rzburg group has developed a full MAGIC analysis package,
|
---|
418 | flexible and modular enough to easily process DWARF data
|
---|
419 | \citep{Bretz:2005paris,Riegel:2005icrc,Bretz:2005mars}. A method for
|
---|
420 | absolute light calibration of the PMs based on Muon images, especially
|
---|
421 | important for long-term monitoring, has been
|
---|
422 | adapted and further improved for the MAGIC telescope
|
---|
423 | \citep{Meyer:Diploma,Goebel:2005}. Both, data analysis and Monte Carlo
|
---|
424 | production, have been fully automatized, such that both can run with
|
---|
425 | sparse user interaction \citep{Dorner:2005icrc}. The analysis was
|
---|
426 | developed to be powerful and as robust as possible to be best suited
|
---|
427 | for automatic processing \citep{Dorner:2005paris}. Experience with
|
---|
428 | large amount of data (up to 8\,TB/month) has been gained since 2004.
|
---|
429 | The datacenter is equipped with a professional multi-stage
|
---|
430 | (hierarchical) storage system. Two operators are paid by the physics
|
---|
431 | faculty. Currently efforts in W\"{u}rzburg and Dortmund are ongoing to
|
---|
432 | turn the old, inflexible Monte Carlo programs, used by the MAGIC
|
---|
433 | collaboration, into modular packages allowing for easy simulation of
|
---|
434 | other setups. Experience with Monte Carlo simulations, especially
|
---|
435 | CORSIKA, is contributed by the Dortmund group, which has actively
|
---|
436 | implemented changes into the CORSIKA program, such as an extension to
|
---|
437 | large zenith angles, prompt meson production and a new atmospheric
|
---|
438 | model \citep{Haffke:Dipl,Schroeder:PhD} for the local atmosphere of La
|
---|
439 | Palma. Furthermore the group has developed high precision Monte Carlos
|
---|
440 | for Lepton propagation in different media \citep{Chirkin:2004}.
|
---|
441 | An energy unfolding method and program has been adapted for IceCube and
|
---|
442 | MAGIC data analysis \citep{Curtef:CM,Muenich:ICRC}.
|
---|
443 |
|
---|
444 | \paragraph{Phenomenology}
|
---|
445 |
|
---|
446 | Both groups have experience with source models and theoretical
|
---|
447 | computations of gamma-ray and neutrino spectra expected from blazars.
|
---|
448 | The relation between the two messengers is a prime focus of interest.
|
---|
449 | Experience with corresponding multi-messenger data analyses involving
|
---|
450 | MAGIC and IceCube data is available in the Dortmund group. Research
|
---|
451 | activities are also related with relativistic particle acceleration
|
---|
452 | \citep{Meli} and gamma-ray attenuation \citep{Kneiske}. The W\"{u}rzburg
|
---|
453 | group has organized and carried out multi-wavelength observations of
|
---|
454 | bright blazars involving MAGIC, Suzaku, the IRAM telescopes and the
|
---|
455 | KVA optical telescope \citep{Ruegamer}. Signatures of supermassive
|
---|
456 | black hole binaries, which are most relevant also for gravitational
|
---|
457 | wave detectors, are investigated jointly with the German LISA
|
---|
458 | consortium (Burkart, Elbracht ongoing research, funded by DLR).
|
---|
459 | \mbox{Secondary} gamma-rays due to dark matter annihilation events are
|
---|
460 | investigated both from their particle physics and astrophysics aspects.
|
---|
461 | Another main focus of research is on models of radiation and particle
|
---|
462 | acceleration processes in blazar jets (hadronic and leptonic models),
|
---|
463 | leading to predictions of correlated neutrino emission \citep{Rueger}.
|
---|
464 | This includes simulations of particle acceleration due to the Weibel
|
---|
465 | instability \citep{Burkart}. Much of this research at W\"{u}rzburg is
|
---|
466 | carried out in the context of the research training school GRK\,1147
|
---|
467 | {\em Theoretical Astrophysics and Particle Physics}.
|
---|
468 |
|
---|
469 | \section[3]{Goals and Work Schedule (Ziele und Arbeitsprogramm)}
|
---|
470 |
|
---|
471 | \subsection[3.1]{Goals (Ziele)}
|
---|
472 |
|
---|
473 | The aim of the project is to put the former CT3 of the HEGRA
|
---|
474 | collaboration on the Roque de los Muchachos back into operation. It
|
---|
475 | will be setup, under the name DWARF, with an enlarged mirror surface
|
---|
476 | (fig.~\ref{DWARF}), a new camera with higher quantum efficiency and new
|
---|
477 | fast data acquisition system. The energy threshold will be lowered, and
|
---|
478 | the sensitivity of DWARF will be greatly improved compared to HEGRA CT3
|
---|
479 | (see fig.~\ref{sensitivity}). Commissioning and the first year of data
|
---|
480 | taking should be carried out within the three years of the requested
|
---|
481 | funding period.
|
---|
482 |
|
---|
483 | \begin{figure}[ht]
|
---|
484 | \begin{center}
|
---|
485 | \includegraphics*[width=0.496\textwidth,angle=0,clip]{CT3.eps}
|
---|
486 | \includegraphics*[width=0.496\textwidth,angle=0,clip]{DWARF.eps}
|
---|
487 | \caption{The old CT3 telescope as operated within the
|
---|
488 | HEGRA System (left) and a photomontage of the revised CT3 telescope
|
---|
489 | with more and hexagonal mirrors (right).}
|
---|
490 | \label{CT3}
|
---|
491 | \label{DWARF}
|
---|
492 | \end{center}
|
---|
493 | \end{figure}
|
---|
494 |
|
---|
495 | The telescope will be operated robotically to reduce costs and man
|
---|
496 | power demands. Furthermore, we seek to obtain know-how for the
|
---|
497 | operation of future networks of robotic Cherenkov telescopes (e.g. a
|
---|
498 | monitoring array around the globe or CTA) or telescopes at sited
|
---|
499 | difficult to access. From the experience with the construction and
|
---|
500 | operation of MAGIC or HEGRA, the proposing groups consider the planned
|
---|
501 | focused approach (small number of experienced scientists) as optimal
|
---|
502 | for achieving the project goals. The available automatic analysis
|
---|
503 | package developed by the W\"{u}rzburg group for MAGIC is modular and
|
---|
504 | flexible, and can thus be used with minor changes for the DWARF
|
---|
505 | project.
|
---|
506 |
|
---|
507 | \begin{figure}[htb]
|
---|
508 | \begin{center}
|
---|
509 | \includegraphics*[width=0.7\textwidth,angle=0,clip]{visibility.eps}
|
---|
510 | \caption{Source visibility in hours per night versus month of the year
|
---|
511 | considering a maximum observation zenith angle of 65$^\circ$
|
---|
512 | for all sources which we want to monitor including the Crab Nebula,
|
---|
513 | necessary for calibration and quality assurance.}
|
---|
514 | \label{visibility}
|
---|
515 | \end{center}
|
---|
516 | \end{figure}
|
---|
517 |
|
---|
518 | The scientific focus of the project will be on the long-term monitoring
|
---|
519 | of bright, nearby VHE emitting blazars. At least one of the proposed
|
---|
520 | targets will be visible any time of the year (see
|
---|
521 | fig.~\ref{visibility}). For calibration purposes, some time will be
|
---|
522 | scheduled for observations of the Crab \mbox{Nebula}.\\
|
---|
523 |
|
---|
524 | The blazar observations will allow
|
---|
525 | \begin{itemize}
|
---|
526 | \item to determine the baseline emission, the duty cycle and the power
|
---|
527 | spectrum of flux variations.
|
---|
528 | \item to cooperate with the Whipple monitoring telescope for an
|
---|
529 | extended time coverage.
|
---|
530 | \item to prompt Target-of-Opportunity (ToO) observations with MAGIC in
|
---|
531 | the case of flares increasing time resolution. Corresponding
|
---|
532 | ToO proposals to H.E.S.S.\ and VERITAS are in preparation.
|
---|
533 | \item to observe simultaneously with MAGIC which will provide an
|
---|
534 | extended bandwidth from below 100\,GeV to multi-TeV energies.
|
---|
535 | \item to obtain multi-frequency observations together with the
|
---|
536 | Mets\"{a}hovi Radio Observatory and the optical telescopes of the
|
---|
537 | Tuorla Observatory. The measurements will be correlated with INTEGRAL
|
---|
538 | and GLAST results, when available. X-ray monitoring using the SWIFT and
|
---|
539 | Suzaku facilities will be proposed.
|
---|
540 |
|
---|
541 | \end{itemize}
|
---|
542 |
|
---|
543 | Interpretation of the data will yield crucial information about
|
---|
544 | \begin{itemize}
|
---|
545 | \item the nature of the emission processes going on in relativistic
|
---|
546 | jets. We plan to interpret the data with models currently developed in
|
---|
547 | the context of the Research Training Group {\em Theoretical
|
---|
548 | Astrophysics} in W\"{u}rzburg (Graduiertenkolleg, GK\,1147), including
|
---|
549 | particle-in-cell and hybrid MHD models.
|
---|
550 | \item the black hole mass and accretion rate fitting the data with
|
---|
551 | emission models. Results will be compared with estimates of the black
|
---|
552 | hole mass from the Magorrian relation.
|
---|
553 | \item the flux of relativistic protons (ions) by correlating the rate
|
---|
554 | of neutrinos detected with the neutrino telescope IceCube and the rate
|
---|
555 | of gamma-ray photons detected with DWARF, and thus the rate of escaping
|
---|
556 | cosmic rays.
|
---|
557 | \item the orbital modulation owing to a supermassive binary black hole.
|
---|
558 | Constraints on the binary system will allow to compute most accurate
|
---|
559 | templates of gravitational waves, which is a connected project at
|
---|
560 | W\"{u}rzburg in the German LISA consortium funded by DLR.
|
---|
561 | \end{itemize}
|
---|
562 |
|
---|
563 | \subsection[3.2]{Work schedule (Arbeitsprogramm)}
|
---|
564 |
|
---|
565 | To complete the mount to a functional Cherenkov telescope within a
|
---|
566 | period of one year, the following steps are necessary:
|
---|
567 |
|
---|
568 | The work schedule assumes, that the work will begin in January 2008,
|
---|
569 | immediately after funding. Later funding would accordingly shift the
|
---|
570 | schedule. Each year is divided into quarters (see fig.~\ref{schedule}).
|
---|
571 |
|
---|
572 | \begin{figure}[htb]
|
---|
573 | \begin{center}
|
---|
574 | \includegraphics*[width=\textwidth,angle=0,clip]{schedule.eps}
|
---|
575 | \caption{Work schedule for the expected funding period of three years.
|
---|
576 | More details about the work distribution is given in the text.}
|
---|
577 | \label{schedule}
|
---|
578 | %\label{DWARF}
|
---|
579 | \end{center}
|
---|
580 | \end{figure}
|
---|
581 |
|
---|
582 | \paragraph{Software}
|
---|
583 | \begin{itemize}
|
---|
584 | \item MC adaption (Do/W\"{u}): Due to the large similarities with the
|
---|
585 | MAGIC telescope, within half a year new Monte Carlo code can be
|
---|
586 | programmed using parts of the existing MAGIC Monte Carlo code. For
|
---|
587 | tests and cross-checks another period of six months is necessary.
|
---|
588 | \item Analysis adaption (W\"{u}): The modular concept of the Magic
|
---|
589 | Analysis and Reconstruction Software (MARS) allows a very fast adaption
|
---|
590 | of the telescope setup, camera and data acquisition properties within
|
---|
591 | half a year.
|
---|
592 | \item Adaption Drive software (W\"{u}): Since the new drive electronics
|
---|
593 | will be based on the design of the MAGIC~II drive system the control
|
---|
594 | software can be reused unchanged. The integration into the new slow
|
---|
595 | control system will take about half a year. It has to be finished at
|
---|
596 | the time of arrival of the drive system components in 2009/1.
|
---|
597 | \item Slow control/DAQ (Do): A new data acquisition and slow control
|
---|
598 | system for camera and auxiliary systems has to be developed. Based on
|
---|
599 | experiences with the AMANDA DAQ, the Domino DAQ developed for MAGIC~II
|
---|
600 | will be adapted and the slow control integrated within three quarters
|
---|
601 | of a year. Commissioning will take place with the full system in
|
---|
602 | 2009/3.
|
---|
603 | \end{itemize}
|
---|
604 |
|
---|
605 | \paragraph{Mirrors (W\"{u})} First prototypes for the mirrors are
|
---|
606 | already available. After testing (six months), the production will
|
---|
607 | start in summer 2008, and the shipment will be finished before the full
|
---|
608 | system assembly 2009/2.
|
---|
609 | \paragraph{Drive (W\"{u})} After a planning phase of half a year to
|
---|
610 | simplify the MAGIC~II drive system for a smaller telescope (together
|
---|
611 | with the delivering company), ordering, production and shipment should
|
---|
612 | be finished in 2009/1. The MAGIC~I and~II drive systems have been
|
---|
613 | planned and implemented successfully by the W\"{u}rzburg group.
|
---|
614 | \paragraph{Auxiliary (W\"{u})} Before the final setup in 2009/1, all
|
---|
615 | auxiliary systems (weather station, computers, etc.) will have been
|
---|
616 | specified, ordered and shipped.
|
---|
617 | \paragraph{Camera (Do)} The camera has to be ready six month after the
|
---|
618 | shipment of the other mechanical parts of the telescope. For this
|
---|
619 | purpose camera tests have to take place in 2009/2, which requires the
|
---|
620 | assembly of the camera within six months before. By now, a PM test
|
---|
621 | bench is set up in Dortmund, which allows to finish planning and
|
---|
622 | ordering of parts of the camera, including the PMs, until summer 2008,
|
---|
623 | before the construction begins.
|
---|
624 | In addition to the manpower permanently provided by Dortmund
|
---|
625 | for production and commissioning, two engineers will participate in the
|
---|
626 | construction phase.
|
---|
627 | \paragraph{Full System (Do/W\"{u})} The full system will be assembled
|
---|
628 | after the delivery of all parts in the beginning of spring 2009. Start of
|
---|
629 | the commissioning is planned four months later. First light is expected
|
---|
630 | in autumn 2009. This would allow an immediate full system test with a
|
---|
631 | well measured, strong and steady source (Crab Nebula). After the
|
---|
632 | commissioning phase will have been finished in spring 2010, complete
|
---|
633 | robotic operation will be provided.
|
---|
634 |
|
---|
635 | Based on the experience with setting up the MAGIC telescope we estimate
|
---|
636 | this workschedule as conservative.
|
---|
637 |
|
---|
638 | \subsection[3.3]{Experiments with humans (Untersuchungen am Menschen)}
|
---|
639 | none
|
---|
640 | \subsection[3.4]{Experiments with animals (Tierversuche)}
|
---|
641 | none
|
---|
642 | \subsection[3.5]{Experiments with recombinant DNA (Gentechnologische Experimente)}
|
---|
643 | none
|
---|
644 |
|
---|
645 | \clearpage
|
---|
646 |
|
---|
647 | \section[4]{Funds requested (Beantragte Mittel)}
|
---|
648 |
|
---|
649 | Summarizing, the expenses for the telescope are dominated by the camera
|
---|
650 | and data acquisition. We request funding for a total of three years.
|
---|
651 | %The financial volume for the complete hardware inclusive
|
---|
652 | %transport amounts to {\bf 372.985,-\,\euro}.
|
---|
653 |
|
---|
654 | \subsection[4.1]{Required Staff (Personalkosten)}
|
---|
655 |
|
---|
656 | For this period, we request funding for two postdocs and two PhD
|
---|
657 | students, one in Dortmund and one in W\"{u}rzburg each (3\,x\,TV-L13).The
|
---|
658 | staff members shall fulfill the tasks given in the work schedule above.
|
---|
659 | To cover these tasks completely, one additional PhD and a various
|
---|
660 | number of Diploma students will complete the working group.
|
---|
661 |
|
---|
662 | Suitable candidates interested in these positions are Dr.\ Thomas
|
---|
663 | Bretz, Dr.\ dest.\ Daniela Dorner, Dr.\ dest.\ Kirsten M\"{u}nich,
|
---|
664 | cand.\ phys.\ Michael Backes, cand.\ phys.\ Daniela Hadasch and cand.\
|
---|
665 | phys.\ Dominik Neise.
|
---|
666 |
|
---|
667 | \subsection[4.2]{Scientific equipment (Wissenschaftliche Ger\"{a}te)}
|
---|
668 |
|
---|
669 | At the Observatorio del Roque de los Muchachos (ORM), at the MAGIC site,
|
---|
670 | the mount of the former HEGRA telescope CT3 now owned by the MAGIC
|
---|
671 | collaboration is still serviceable. One hut for electronics close to
|
---|
672 | the telescope is available. Additional space is available in the MAGIC
|
---|
673 | counting house. The MAGIC Memorandum of Understanding allows for
|
---|
674 | operating DWARF as an auxiliary instrument (see appendix). Also
|
---|
675 | emergency support from the shift crew is guaranteed, although
|
---|
676 | autonomous robotic operation is the primary goal.
|
---|
677 |
|
---|
678 | \begin{figure}[hb]
|
---|
679 | \centering{
|
---|
680 | %\includegraphics[width=0.605\textwidth]{sensitivity.eps}
|
---|
681 | \includegraphics[width=0.70\textwidth]{sensitivity.eps}
|
---|
682 | \caption{Integral flux sensitivity of several telescopes
|
---|
683 | \citep{Juan:2000,MAGICsensi,Vassiliev:1999}
|
---|
684 | and the expectation for DWARF, with both a PMT- and a
|
---|
685 | GAPD-camera, scaled from the sensitivity of
|
---|
686 | HEGRA~CT1 by the improvements mentioned in the text.
|
---|
687 | } \label{sensitivity} }
|
---|
688 | \end{figure}
|
---|
689 |
|
---|
690 | To achieve the planned sensitivity and threshold
|
---|
691 | (fig.~\ref{sensitivity}), the following components have to be bought.
|
---|
692 | To obtain reliable results as fast as possible well known components
|
---|
693 | have been chosen.\\
|
---|
694 |
|
---|
695 | {\bf Camera}\dotfill 206.450,-\,\euro\\[-3ex]
|
---|
696 | \begin{quote}
|
---|
697 | To setup a camera with 313 pixels the following components are needed:\\
|
---|
698 | \parbox[t]{1em}{~}\begin{minipage}[t]{0.6\textwidth}
|
---|
699 | Photomultiplier Tube EMI\,9083B\hfill 220,-\,\euro\\
|
---|
700 | Active voltage divider (EMI)\hfill 80,-\,\euro\\
|
---|
701 | High voltage support and control\hfill 300,-\,\euro\\
|
---|
702 | Preamplifier\hfill 50,-\,\euro\\
|
---|
703 | Spare parts (overall)\hfill 3000,-\,\euro\\
|
---|
704 | \end{minipage}\\[-0.5ex]
|
---|
705 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
706 | For long-term observations, the stability of the camera is a major
|
---|
707 | criterion. To keep the systematic errors small, a good background
|
---|
708 | estimation is mandatory. The only possibility for a synchronous
|
---|
709 | determination of the background is the measurement from the night-sky
|
---|
710 | observed in the same field-of-view with the same instrument. To achieve
|
---|
711 | this, the observed position is moved out of the camera center which
|
---|
712 | allows the estimation of the background from positions symmetric with
|
---|
713 | respect to the camera center (so called Wobble mode). This observation
|
---|
714 | mode increases the sensitivity by a factor of $\sqrt{2}$, because
|
---|
715 | spending observation time for dedicated background observations becomes
|
---|
716 | obsolete, i.e.\ observation time for the source is doubled. This
|
---|
717 | ensures in addition a better time coverage of the observed sources.\\
|
---|
718 | A further increase in sensitivity can be achieved by better background
|
---|
719 | statistics from not only one but several independent positions for the
|
---|
720 | background estimation in the camera \citep{Lessard:2001}. To allow for
|
---|
721 | this the source position in Wobble mode should be shifted
|
---|
722 | $0.6^\circ-0.7^\circ$ out of the camera center.
|
---|
723 |
|
---|
724 | A camera completely containing the shower images of events in the energy
|
---|
725 | region of 1\,TeV-10\,TeV should have a diameter in the order of
|
---|
726 | 5$^\circ$. To decrease the dependence of the measurements on the camera
|
---|
727 | geometry, a camera layout as symmetric as possible will be chosen.
|
---|
728 | Consequently a camera allowing to fulfill these requirements should be
|
---|
729 | round and have a diameter of $4.5^\circ-5.0^\circ$.
|
---|
730 | \begin{figure}[th]
|
---|
731 | \begin{center}
|
---|
732 | \includegraphics*[width=0.495\textwidth,angle=0,clip]{cam271.eps}
|
---|
733 | \includegraphics*[width=0.495\textwidth,angle=0,clip]{cam313.eps}
|
---|
734 | \caption{Left: Schematic picture of the 271 pixel CT3 camera with a field of view of 4.6$^\circ$.
|
---|
735 | Right: Schematic picture of the 313 pixel camera for DWARF with a field of view of 5$^\circ$.}
|
---|
736 | \label{camCT3}
|
---|
737 | \label{camDWARF}
|
---|
738 | \end{center}
|
---|
739 | \end{figure}
|
---|
740 |
|
---|
741 | Therefore a camera with 313 pixel camera (see fig.~\ref{camDWARF}) is
|
---|
742 | chosen. The camera will be built based on the experience with HEGRA and
|
---|
743 | MAGIC. 19\,mm diameter Photomultiplier Tubes (PM, EMI\,9083B/KFLA-UD)
|
---|
744 | will be bought, similar to the HEGRA type (EMI\,9083\,KFLA). They have
|
---|
745 | a quantum efficiency improved by 25\% (see fig.~\ref{qe}) and ensure a
|
---|
746 | granularity which is enough to guarantee good results even below the
|
---|
747 | energy threshold (flux peak energy). Each individual pixel has to be
|
---|
748 | equipped with a preamplifier, an active high-voltage supply and
|
---|
749 | control. The total expense for a single pixel will be in the order of
|
---|
750 | 650,-\,\euro.
|
---|
751 |
|
---|
752 | All possibilities of borrowing one of the old HEGRA cameras for a
|
---|
753 | transition time have been probed and refused by the owners of the
|
---|
754 | cameras.
|
---|
755 |
|
---|
756 | At ETH~Z\"{u}rich currently test measurements are ongoing to prove the
|
---|
757 | ability, i.e.\ stability, aging, quantum efficiency, etc., of using
|
---|
758 | Geiger-mode APDs (GAPD) as photon detectors in the camera of a
|
---|
759 | Cherenkov telescope. The advantages are an extremely high quantum
|
---|
760 | efficiency ($>$50\%), easier gain stabilization and simplified
|
---|
761 | application compared to classical PMs. If these test measurements are
|
---|
762 | successfully finished until 8/2008, we consider to use GAPDs in favor
|
---|
763 | of classical PMs. The design of such a camera would take place at
|
---|
764 | University Dortmund in close collaboration with the experts from ETH.
|
---|
765 | The construction would also take place at the electronics workshop of
|
---|
766 | Dortmund.
|
---|
767 |
|
---|
768 | \end{quote}\vspace{3ex}
|
---|
769 |
|
---|
770 | {\bf Camera support}\dotfill 7.500,-\,\euro\\[-3ex]
|
---|
771 | \begin{quote}
|
---|
772 | For this setup the camera holding has to be redesigned. (1500,-\,\euro)
|
---|
773 | The camera chassis must be water tight and will be equipped with an
|
---|
774 | automatic lid, protecting the PMs at daytime. For further protection, a
|
---|
775 | plexi-glass window will be installed in front of the camera. By coating
|
---|
776 | this window with an anti-reflex layer of magnesium-fluoride, a gain in
|
---|
777 | transmission of 5\% is expected. Each PM will be equipped with a
|
---|
778 | light-guide (Winston cone) as developed by UC Davis and successfully in
|
---|
779 | operation in the MAGIC camera. (3000,-\,\euro\ for all Winston cones). The
|
---|
780 | current design will be improved by using a high reflectivity aluminized
|
---|
781 | Mylar mirror-foil, coated with a dialectical layer ($Si\,O_2$
|
---|
782 | alternated with Niobium Oxide), to reach a reflectivity in the order of
|
---|
783 | 98\%. An electric and optical shielding of the individual PMs is
|
---|
784 | planned.
|
---|
785 |
|
---|
786 | In total a gain of $\sim$15\% in light-collection
|
---|
787 | efficiency compared to the old CT3 system can be achieved.
|
---|
788 | \end{quote}\vspace{3ex}
|
---|
789 |
|
---|
790 | \newpage
|
---|
791 | {\bf Data acquisition}\dotfill 61.035,-\,\euro\\[-3ex]
|
---|
792 | \begin{quote}
|
---|
793 | 313 pixels a\\
|
---|
794 | \parbox[t]{1em}{~}\begin{minipage}[t]{0.6\textwidth}
|
---|
795 | Readout\hfill 95,-\,\euro\\
|
---|
796 | Trigger\hfill 100,-\,\euro\\
|
---|
797 | \end{minipage}\\[-0.5ex]
|
---|
798 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
799 | For the data acquisition system a hardware readout based on an analog
|
---|
800 | ring buffer (Domino\ II/IV), currently developed for the MAGIC~II
|
---|
801 | readout, will be used \citep{Barcelo}. This technology allows to sample
|
---|
802 | the pulses with high frequencies and readout several channels with a
|
---|
803 | single Flash-ADC resulting in low costs. The low power consumption will
|
---|
804 | allow to include the digitization near the signal source making
|
---|
805 | the transfer of the analog signal obsolete. This results in less
|
---|
806 | pick-up noise and reduces the signal dispersion. By high sampling rates
|
---|
807 | (1.2\,GHz), additional information about the pulse shape can be
|
---|
808 | obtained. This increases the over-all sensitivity further, because the
|
---|
809 | short integration time allows for almost perfect suppression of noise
|
---|
810 | due to night-sky background photons. The estimated trigger-, i.e.\
|
---|
811 | readout-rate of the telescope is below 100\,Hz (HEGRA: $<$10\,Hz) which
|
---|
812 | allows to use a low-cost industrial solution for readout of the system,
|
---|
813 | like USB\,2.0.
|
---|
814 |
|
---|
815 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
816 | Current results obtained with the new 2\,GHz FADC system in the MAGIC
|
---|
817 | data acquisition show, that for a single telescope a sensitivity
|
---|
818 | improvement of 40\% with a fast FADC system is achievable \citep{Tescaro:2007}.
|
---|
819 |
|
---|
820 | Like for the HEGRA telescopes a simple multiplicity trigger is
|
---|
821 | sufficient, but also a simple neighbor-logic could be programmed (both
|
---|
822 | cases $\sim$100,-\,\euro/channel).
|
---|
823 |
|
---|
824 | Additional data reduction and preprocessing within the readout chain is
|
---|
825 | provided. Assuming conservatively a readout rate of 30\,Hz, the storage
|
---|
826 | space needed will be less than 250\,GB/month or 3\,TB/year. This amount
|
---|
827 | of data can easily be stored and processed by the W\"{u}rzburg
|
---|
828 | Datacenter (current capacity $>$80\,TB, $>$40\,CPUs).
|
---|
829 | \end{quote}\vspace{3ex}
|
---|
830 |
|
---|
831 | {\bf Mirrors}\dotfill 15.000,-\,\euro\\[-3ex]
|
---|
832 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
833 | \begin{quote}
|
---|
834 | The existing mirrors will be replaced by new plastic mirrors currently
|
---|
835 | developed by Wolfgang Dr\"{o}ge's group. The cheap and light-weight
|
---|
836 | material has been formerly used for Winston cones in balloon
|
---|
837 | experiments. The mirrors are copied from a master and coated with a
|
---|
838 | reflecting and a protective material. Tests have given promising
|
---|
839 | results. By a change of the mirror geometry, the mirror area can be
|
---|
840 | increased from 8.5\,m$^2$ to 13\,m$^2$ (see picture~\ref{CT3} and
|
---|
841 | montage~\ref{DWARF}). This includes an increase of $\sim$10$\%$ per
|
---|
842 | mirror by using a hexagonal layout instead of a round one. A further
|
---|
843 | increase of the mirror area would require a reconstruction of parts of
|
---|
844 | the mount and will therefore be considered only in a later phase of the
|
---|
845 | experiment.
|
---|
846 |
|
---|
847 | If the current development of the plastic mirrors cannot be finished in
|
---|
848 | time, a re-machining of the old glass mirrors (8.5\,m$^2$) is possible
|
---|
849 | with high purity aluminum and quartz coating.
|
---|
850 |
|
---|
851 | In both cases the mirrors can be coated with the same high reflectivity
|
---|
852 | aluminized Mylar mirror-foil and a dialectical layer of $SiO_2$ as for
|
---|
853 | the Winston cones. By this, a gain in reflectivity of $\sim10\%$ is
|
---|
854 | achieved, see fig.~\ref{reflectivity} \citep{Fraunhofer}. Both
|
---|
855 | solutions would require the same expenses.
|
---|
856 |
|
---|
857 | To keep track of the alignment, reflectivity and optical quality of the
|
---|
858 | individual mirrors and the point-spread function of the total mirror
|
---|
859 | during long-term observations, the application of an automatic mirror
|
---|
860 | adjustment system, as developed by ETH~Z\"{u}rich and successfully
|
---|
861 | operated on the MAGIC telescope, is intended.
|
---|
862 |
|
---|
863 | %<grey>The system
|
---|
864 | %will be provided by ETH Z"urich.</grey>
|
---|
865 |
|
---|
866 | %{\bf For a diameter mirror of less than 2.4\,m, the delay between an
|
---|
867 | %parabolic (isochronous) and a spherical mirror shape at the edge is well
|
---|
868 | %below 1ns (see figure). Thus for a sampling rate of 1.2\,GHz parabolic
|
---|
869 | %individual mirrors are not needed. Due to their small size the
|
---|
870 | %individual mirrors can have a spherical shape.}
|
---|
871 | %}\\[2ex]
|
---|
872 | \end{quote}\vspace{3ex}
|
---|
873 |
|
---|
874 | {\bf Calibration System}\dotfill 9.650,-\,\euro\\[-3ex]
|
---|
875 | \begin{quote}
|
---|
876 | Components\\
|
---|
877 | \parbox[t]{1em}{~}\begin{minipage}[t]{0.6\textwidth}
|
---|
878 | Absolute light calibration\hfill 2.000,-\,\euro\\
|
---|
879 | Individual pixel rate control\hfill 3.000,-\,\euro\\
|
---|
880 | Weather station\hfill 500,-\,\euro\\
|
---|
881 | GPS clock\hfill 1.500,-\,\euro\\
|
---|
882 | CCD cameras with readout\hfill 2.650,-\,\euro\\
|
---|
883 | \end{minipage}\\[-0.5ex]
|
---|
884 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
885 | For the absolute light calibration (gain-calibration) of the PMs a
|
---|
886 | calibration box, as successfully used in the MAGIC telescope, will be
|
---|
887 | produced.
|
---|
888 |
|
---|
889 | To ensure a homogeneous acceptance of the camera, essential for
|
---|
890 | Wobble mode observations, the trigger rate of the individual pixels
|
---|
891 | will be measured and controlled.
|
---|
892 |
|
---|
893 | For a correction of axis misalignments and possible deformations of the
|
---|
894 | structure (e.g.\ bending of camera holding masts) a pointing correction
|
---|
895 | algorithm will be applied, as used in the MAGIC tracking system. It is
|
---|
896 | calibrated by measurements of the reflection of bright guide stars on
|
---|
897 | the camera surface and ensures a pointing accuracy well below the pixel
|
---|
898 | diameter. Therefore a high sensitive low-cost video camera, as for
|
---|
899 | MAGIC\ I and~II, (300,-\,\euro\ camera, 600,-\,\euro\ optics,
|
---|
900 | 300,-\,\euro\ housing, 250,-\,\euro\ frame grabber) will be installed.
|
---|
901 |
|
---|
902 | A second identical CCD camera for online monitoring (starguider) will
|
---|
903 | be bought.
|
---|
904 |
|
---|
905 | For an accurate tracking a GPS clock is necessary. The weather station
|
---|
906 | helps judging the data quality.
|
---|
907 | %}\\[2ex]
|
---|
908 | \end{quote}\vspace{3ex}
|
---|
909 |
|
---|
910 | {\bf Computing}\dotfill 12.000,-\,\euro\\[-3ex]
|
---|
911 | \begin{quote}
|
---|
912 | \parbox[t]{1em}{~}\begin{minipage}[t]{0.6\textwidth}
|
---|
913 | Three PCs\hfill 8.000,-\,\euro\\
|
---|
914 | SATA RAID 3TB\hfill 4.000,-\,\euro\\
|
---|
915 | \end{minipage}\\[-0.5ex]
|
---|
916 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
917 | For on-site computing three standard PCs are needed ($\sim$8.000,-\,\euro).
|
---|
918 | This includes readout and storage, preprocessing and telescope control.
|
---|
919 | For safety reasons, a firewall is mandatory. For local cache-storage
|
---|
920 | and backup, two RAID\,5 SATA disk arrays with one Terabyte capacity
|
---|
921 | each will fulfill the requirement ($\sim$4.000,-\,\euro). The data will be
|
---|
922 | transmitted as soon as possible after data taking via Internet to the
|
---|
923 | W\"{u}rzburg Datacenter. Enough storage capacity and computing power
|
---|
924 | is available there and already reserved for this purpose.
|
---|
925 |
|
---|
926 | Monte Carlo production and storage will take place at University
|
---|
927 | Dortmund.%}\\[2ex]
|
---|
928 | \end{quote}\vspace{3ex}
|
---|
929 |
|
---|
930 | %%%%%%%%%%%%%% PLOTS HERE???? %%%%%%%%%%%%%%%%%%%%%%%%%%
|
---|
931 |
|
---|
932 | {\bf Mount and Drive}\dotfill 17.500,-\,\euro\\[-3ex]
|
---|
933 | \begin{quote}
|
---|
934 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
935 | The present mount is used. Only a smaller investment for safety,
|
---|
936 | corrosion protection, cable ducts, etc. is needed (7.500,-\,\euro).
|
---|
937 |
|
---|
938 | Motors, shaft encoders and control electronics in the order of
|
---|
939 | 10.000,-\,\euro\ have to be bought. The costs have been estimated with
|
---|
940 | the experience from building the MAGIC drive systems. The DWARF drive
|
---|
941 | system should allow for relatively fast repositioning for three
|
---|
942 | reasons: (i)~Fast movement might be mandatory for future ToO
|
---|
943 | observations. (ii)~Wobble mode observations will be done changing the
|
---|
944 | Wobble-position continuously (each 20\,min) for symmetry reasons.
|
---|
945 | (iii)~To ensure good time coverage of more than one source visible at
|
---|
946 | the same time, the observed source will be changed in constant time
|
---|
947 | intervals.
|
---|
948 |
|
---|
949 | For the drive system three 150\,Watt servo motors are intended to be bought. A
|
---|
950 | micro-controller based motion control unit (Siemens SPS L\,20) similar to
|
---|
951 | the one of the current MAGIC~II drive system will be used. For
|
---|
952 | communication with the readout-system, a standard Ethernet connection
|
---|
953 | based on the TCP/IP- and UDP-protocol will be setup.
|
---|
954 | %}\\[2ex]
|
---|
955 | \end{quote}\vspace{3ex}
|
---|
956 |
|
---|
957 | {\bf Security}\dotfill 4.000,-\,\euro\\[-3ex]
|
---|
958 | \begin{quote}
|
---|
959 | \parbox[t]{1em}{~}\begin{minipage}[t]{0.6\textwidth}
|
---|
960 | Uninterruptable power-supply (UPS)\hfill 2.000,-\,\euro\\
|
---|
961 | Security fence\hfill 2.000,-\,\euro\\
|
---|
962 | \end{minipage}\\[-0.5ex]
|
---|
963 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
964 | A UPS with 5\,kW-10\,kW will be
|
---|
965 | installed to protect the equipment against power cuts and ensure a safe
|
---|
966 | telescope position at the time of sunrise.
|
---|
967 |
|
---|
968 | For protection in case of robotic movement a fence will be
|
---|
969 | installed.%}\\[2ex]
|
---|
970 | \end{quote}\vspace{3ex}
|
---|
971 |
|
---|
972 | {\bf Other expenses}\dotfill 7.500,-\,\euro\\[-3ex]
|
---|
973 | \begin{quote}
|
---|
974 | %\parbox[t]{1em}{~}\begin{minipage}[t]{0.6\textwidth}
|
---|
975 | % Robotics\hfill 7.500,-\,\euro\\
|
---|
976 | % \end{minipage}\\[-0.5ex]
|
---|
977 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
978 | For remote, robotic operation a variety of remote controllable electronic
|
---|
979 | components such as Ethernet controlled sockets and switches will be
|
---|
980 | bought. Monitoring equipment, for example different kind of sensors, is
|
---|
981 | also mandatory.%}\\[2ex]
|
---|
982 | \end{quote}
|
---|
983 | \hspace*{0.66\textwidth}\hrulefill\\[0.5ex]
|
---|
984 | \hspace*{0.66\textwidth}\hspace{0.5ex}\hfill Sum 4.2:\hfill{\bf
|
---|
985 | 341.135,-\,\euro}\hfill\hspace*{0pt}\\[-1ex]
|
---|
986 | \hspace*{0.66\textwidth}\hrulefill\\[-1.9ex]
|
---|
987 | \hspace*{0.66\textwidth}\hrulefill\\
|
---|
988 |
|
---|
989 | \begin{figure}[p]
|
---|
990 | \centering{
|
---|
991 | \includegraphics[width=0.57\textwidth]{cherenkov.eps}
|
---|
992 | \includegraphics[width=0.57\textwidth]{reflectivity.eps}
|
---|
993 | \includegraphics[width=0.57\textwidth]{qe.eps}
|
---|
994 | \caption{Top to bottom: The Cherenkov spectrum as observed by a
|
---|
995 | telescope located at 2000\,m above sea level. The mirror's reflectivity
|
---|
996 | of a 300\,nm thick aluminum layer with a protection layer of 10\,nm and
|
---|
997 | 100\,nm thickness respectively. For comparison the reflectivity of
|
---|
998 | HEGRA CT1's mirrors \citep{Kestel:2000} are shown. The bottom plot depicts
|
---|
999 | the quantum efficiency of the preferred PMs (EMI) together with the
|
---|
1000 | predecessor used in CT1. A proper coating \citep{Paneque:2004} will
|
---|
1001 | further enhance its efficiency. An even better increase would be the
|
---|
1002 | usage of Geiger-mode APDs.}
|
---|
1003 |
|
---|
1004 | \label{cherenkov}
|
---|
1005 | \label{reflectivity}
|
---|
1006 | \label{qe}
|
---|
1007 | }
|
---|
1008 | \end{figure}
|
---|
1009 |
|
---|
1010 | \subsection[4.3]{Consumables (Verbrauchsmaterial)}
|
---|
1011 |
|
---|
1012 | \begin{quote}
|
---|
1013 | % \parbox[t]{1em}{~}\begin{minipage}[t]{0.9\textwidth}
|
---|
1014 | 10 LTO\,4 tapes (8\,TB)\dotfill 750,-\,\euro\\
|
---|
1015 | Consumables (overalls): tools and materials\dotfill 10.000,-\,\euro
|
---|
1016 | % \end{minipage}\\[-0.5ex]
|
---|
1017 | \end{quote}
|
---|
1018 |
|
---|
1019 | \hspace*{0.66\textwidth}\hrulefill\\[0.5ex]
|
---|
1020 | \hspace*{0.66\textwidth}\hspace{0.5ex}\hfill Sum 4.3:\hfill{\bf
|
---|
1021 | 10.750,-\,\euro}\hfill\hspace*{0pt}\\[-1ex]
|
---|
1022 | \hspace*{0.66\textwidth}\hrulefill\\[-1.9ex]
|
---|
1023 | \hspace*{0.66\textwidth}\hrulefill\\
|
---|
1024 |
|
---|
1025 | \subsection[4.4]{Travel expenses (Reisen)}
|
---|
1026 | The large amount of travel funding is required due to the very close
|
---|
1027 | cooperation between Dortmund and W\"{u}rzburg and the work demands on
|
---|
1028 | the construction site.\\[-2ex]
|
---|
1029 |
|
---|
1030 | \begin{quote}
|
---|
1031 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
1032 | Per year one senior group member from Dortmund and W\"{u}rzburg should
|
---|
1033 | present the status of the work in progress at an international workshop
|
---|
1034 | or conference:\\
|
---|
1035 | 2 x 3\,years x 1.500,-\,\euro\dotfill 9.000,-\,\euro\\[-2ex]
|
---|
1036 |
|
---|
1037 | One participation at the biannual MAGIC collaboration meeting:\\
|
---|
1038 | 2 x 3\,years x 1.000,-\,\euro\dotfill 6.000,-\,\euro\\[-2ex]
|
---|
1039 |
|
---|
1040 | PhD student exchange between W\"{u}rzburg and Dortmund:\\
|
---|
1041 | 1\,student x 1\,week x 24 (every six weeks) x 800,-\,\euro\dotfill
|
---|
1042 | 19.200,-\,\euro\\[-2ex]
|
---|
1043 |
|
---|
1044 | For setup of the telescope at La Palma the following travel expenses
|
---|
1045 | are necessary:\\
|
---|
1046 | 4 x 2\,weeks at La Palma x 2\,persons x 1.800,-\,\euro\dotfill
|
---|
1047 | 28.800,-\,\euro
|
---|
1048 | %}
|
---|
1049 | \end{quote}
|
---|
1050 |
|
---|
1051 | \hspace*{0.66\textwidth}\hrulefill\\[0.5ex]
|
---|
1052 | \hspace*{0.66\textwidth}\hspace{0.5ex}\hfill Sum 4.4:\hfill{\bf
|
---|
1053 | 63.000,-\,\euro}\hfill\hspace*{0pt}\\[-1ex]
|
---|
1054 | \hspace*{0.66\textwidth}\hrulefill\\[-1.9ex]
|
---|
1055 | \hspace*{0.66\textwidth}\hrulefill\\
|
---|
1056 |
|
---|
1057 |
|
---|
1058 | \subsection[4.5]{Publication costs (Publikationskosten)}
|
---|
1059 | Will be covered by the proposing institutes.
|
---|
1060 |
|
---|
1061 |
|
---|
1062 | \subsection[4.6]{Other costs (Sonstige Kosten)}
|
---|
1063 | \begin{quote}
|
---|
1064 | Storage container (for shipment of the mirrors)\dotfill 5.000,-\,\euro\\
|
---|
1065 | Transport\dotfill 15.000,-\,\euro\\
|
---|
1066 | Dismantling (will be covered by proposing institutes)\dotfill n/a
|
---|
1067 | \end{quote}
|
---|
1068 |
|
---|
1069 | \hspace*{0.66\textwidth}\hrulefill\\[0.5ex]
|
---|
1070 | \hspace*{0.66\textwidth}\hspace{0.5ex}\hfill Sum 4.6:\hfill{\bf
|
---|
1071 | 20.000,-\,\euro}\hfill\hspace*{0pt}\\[-1ex]
|
---|
1072 | \hspace*{0.66\textwidth}\hrulefill\\[-1.9ex]
|
---|
1073 | \hspace*{0.66\textwidth}\hrulefill\\
|
---|
1074 |
|
---|
1075 | \newpage
|
---|
1076 | \germanTeX
|
---|
1077 | \section[5]{Preconditions for carrying out the project\\(Voraussetzungen f"ur die Durchf"uhrung des Vorhabens)}
|
---|
1078 | none
|
---|
1079 |
|
---|
1080 | \subsection[5.1]{The research team (Zusammensetzung der Arbeitsgruppe)}
|
---|
1081 |
|
---|
1082 | \paragraph{Dortmund}
|
---|
1083 | \begin{itemize}
|
---|
1084 | \setlength{\itemsep}{0pt}
|
---|
1085 | \setlength{\parsep}{0pt}
|
---|
1086 | \item Prof.\ Dr.\ Dr.\ Wolfgang Rhode (Grundauststattung)
|
---|
1087 | \item Dr.\ Tanja Kneiske (Postdoc (Ph"anomenologie), DFG-Forschungsstipendium)
|
---|
1088 | \item Dr.\ Julia Becker (Postdoc (Ph"anomenologie), Drittmittel)
|
---|
1089 | \item Dipl.-Phys.\ Kirsten M"unich (Doktorand (IceCube), Drittmittel)
|
---|
1090 | \item Dipl.-Phys.\ Jens Dreyer (Doktorand (IceCube), Grundauststattung)
|
---|
1091 | \item M.Sc.\ Valentin Curtef (Doktorand (MAGIC), Grundausstattung)
|
---|
1092 | \item cand.\ phys.\ Michael Backes (Diplomand (MAGIC), zum F"orderbeginn diplomiert)
|
---|
1093 | \item cand.\ phys.\ Daniela Hadasch (Diplomand (MAGIC))
|
---|
1094 | \item cand.\ phys.\ Anne Wiedemann (Diplomand (IceCube))
|
---|
1095 | \item cand.\ phys.\ Dominik Neise (Diplomand (MAGIC))
|
---|
1096 | \item Dipl.-Ing.\ Kai Warda (Elektronik)
|
---|
1097 | \item PTA Matthias Domke (Systemadministration)
|
---|
1098 | \end{itemize}
|
---|
1099 |
|
---|
1100 | \paragraph{W\"{u}rzburg}
|
---|
1101 | \begin{itemize}
|
---|
1102 | \setlength{\itemsep}{0pt}
|
---|
1103 | \setlength{\parsep}{0pt}
|
---|
1104 | \item Prof.\ Dr.\ Karl Mannheim (Landesmittel)
|
---|
1105 | \item Prof.\ Dr.\ Thomas Trefzger (Landesmittel)
|
---|
1106 | \item Prof.\ Dr.\ Wolfgang Dr"oge (Landesmittel)
|
---|
1107 | \item Dr.\ Thomas Bretz (Postdoc (MAGIC), BMBF)
|
---|
1108 | \item Dr.\ Felix Spanier (Postdoc, Landesmittel)
|
---|
1109 | \item Dipl.-Phys.\ Jordi Albert (Doktorand, DFG-GRK1147)
|
---|
1110 | \item Dipl.-Phys.\ Karsten Berger (Doktorand (MAGIC), Landesmittel)
|
---|
1111 | \item Dipl.-Phys.\ Thomas Burkart (Doktorand (LISA), DLR)
|
---|
1112 | \item Dipl.-Phys.\ Oliver Elbracht (Doktorand, Elitenetzwerk Bayern)
|
---|
1113 | \item Dipl.-Phys.\ Dominik Els"asser (Doktorand, Elitenetzwerk Bayern)
|
---|
1114 | \item Dipl.-Phys.\ Daniela Dorner (Doktorand (MAGIC), BMBF)
|
---|
1115 | \item Dipl.-Phys.\ Daniel H"ohne (Doktorand (MAGIC), Landesmittel)
|
---|
1116 | \item Dipl.-Phys.\ Markus Meyer (Doktorand, DFG-GRK1147)
|
---|
1117 | \item M.Sc.\ Surajit Paul (Doktorand, DFG-GRK1147)
|
---|
1118 | \item Dipl.-Phys.\ Stefan R"ugamer (Doktorand (MAGIC), Landesmittel)
|
---|
1119 | \item Dipl.-Phys.\ Michael R"uger (Doktorand, Elitenetzwerk Bayern)
|
---|
1120 | \item Dipl.-Phys.\ Martina Wei"s (Doktorand, Elitenetzwerk Bayern)
|
---|
1121 | \item cand.\ phys.\ Sebastian Huber
|
---|
1122 | \item cand.\ phys.\ Tobias Hein
|
---|
1123 | \item cand.\ phys.\ Tobias Viering
|
---|
1124 | \end{itemize}
|
---|
1125 | \originalTeX
|
---|
1126 |
|
---|
1127 | \subsection[5.2]{Cooperation with other scientists\\(Zusammenarbeit mit
|
---|
1128 | anderen Wissenschaftlern)}
|
---|
1129 |
|
---|
1130 | Both applying groups cooperate with the international
|
---|
1131 | MAGIC collaboration and the institutes represented therein. (W\"{u}rzburg
|
---|
1132 | funded by the BMBF, Dortmund by means of appointment for the moment).
|
---|
1133 |
|
---|
1134 | W\"{u}rzburg is also in close scientific exchange with the group of
|
---|
1135 | Prof.~Dr.~Victoria Fonseca, UCM Madrid and the University of Turku
|
---|
1136 | (Finland) operating the KVA optical telescope at La Palma. Other
|
---|
1137 | cooperations refer to the projects JEM-EUSO (science case), GRIPS
|
---|
1138 | (simulation), LISA (astrophysical input for templates), STEREO (data
|
---|
1139 | analysis), and SOLAR ORBITER (electron-proton telescope). A cooperation
|
---|
1140 | with GLAST science team members (Dr.~Anita and Dr.~Olaf Reimer,
|
---|
1141 | Stanford) is also relevant for the proposed project.
|
---|
1142 |
|
---|
1143 | The group in Dortmund is involved in the IceCube experiment (BMBF
|
---|
1144 | funding) and maintains close contacts to the collaboration partners.
|
---|
1145 | Moreover on the field of phenomenology good working contacts exist to
|
---|
1146 | the groups of Prof.~Dr.~Reinhard Schlickeiser, Ruhr-Universit\"{a}t
|
---|
1147 | Bochum and Prof.~Dr.~Peter Biermann, MPIfR Bonn. There are furthermore
|
---|
1148 | intense contacts to Prof.~Dr.~Francis Halzen, Madison, Wisconsin.
|
---|
1149 |
|
---|
1150 | The telescope design will be worked out in close cooperation with the
|
---|
1151 | group of Prof.~Dr.~Felicitas Pauss, Dr.~Adrian Biland and
|
---|
1152 | Prof.~Dr.~Eckart Lorenz (ETH~Z\"{u}rich). They will provide help in design
|
---|
1153 | studies, construction and software development. The DAQ design will be
|
---|
1154 | contributed by the group of Prof.~Dr.~Riccardo Paoletti (Universit\`{a} di
|
---|
1155 | Siena and INFN sez.\ di Pisa, Italy).
|
---|
1156 |
|
---|
1157 | The group of the newly appointed {\em Lehrstuhl f\"{u}r Physik und ihre
|
---|
1158 | Didaktik} (Prof.~Dr.~Thomas Trefzger) has expressed their interest to
|
---|
1159 | join the project. They bring in a laboratory for photo-sensor testing,
|
---|
1160 | know-how from former contributions to ATLAS and a joint interest in
|
---|
1161 | operating a data pipeline using GRID technologies.
|
---|
1162 |
|
---|
1163 | \subsection[5.3]{Work outside Germany, Cooperation with foreign
|
---|
1164 | partners\\(Arbeiten im Ausland, Kooperation mit Partnern im Ausland)}
|
---|
1165 |
|
---|
1166 | The work on DWARF will take place at the ORM on the Spanish island La
|
---|
1167 | Palma. It will be performed in close collaboration with the
|
---|
1168 | MAGIC collaboration.
|
---|
1169 |
|
---|
1170 | \subsection[5.4]{Scientific equipment available (Apparative
|
---|
1171 | Ausstattung)}
|
---|
1172 | In Dortmund and W\"{u}rzburg extensive computer capacities for data
|
---|
1173 | storage as well as for data analysis are available.
|
---|
1174 |
|
---|
1175 | The faculty of physics at the University Dortmund has modern
|
---|
1176 | equipped mechanical and electrical workshops including a department for
|
---|
1177 | development of electronics at its command. The chair of astroparticle
|
---|
1178 | physics possesses common technical equipment required for constructing
|
---|
1179 | modern DAQ.
|
---|
1180 |
|
---|
1181 | The faculty of physics at the University of W\"{u}rzburg comes with a
|
---|
1182 | mechanical and an electronic workshop, as well as a special laboratory
|
---|
1183 | of the chair for astronomy suitable for photosensor testing.
|
---|
1184 |
|
---|
1185 | \subsection[5.5]{The institution's general contribution\\(Laufende
|
---|
1186 | Mittel f\"{u}r Sachausgaben)}
|
---|
1187 |
|
---|
1188 | Current total institute budget from the University Dortmund
|
---|
1189 | $\sim$20.000,-\,\euro\ per year.
|
---|
1190 |
|
---|
1191 | Current total institute budget from the University W\"{u}rzburg
|
---|
1192 | $\sim$30.000,-\,\euro\ per year.
|
---|
1193 |
|
---|
1194 | %\paragraph{5.6 Conflicts of interest in economic activities\\Interessenskonflikte bei wirtschaftlichen Aktivit\"aten}~\\
|
---|
1195 | \subsection[5.6]{Conflicts of interest in economic activities\\(Interessenskonflikte bei wirtschaftlichen Aktivit\"{a}ten)}~\\
|
---|
1196 | none
|
---|
1197 |
|
---|
1198 | \subsection[5.7]{Other requirements (Sonstige Voraussetzungen)}~\\
|
---|
1199 | none
|
---|
1200 |
|
---|
1201 | \newpage
|
---|
1202 | \thispagestyle{empty}
|
---|
1203 |
|
---|
1204 | \paragraph{6 Declarations (Erkl\"{a}rungen)}
|
---|
1205 |
|
---|
1206 | A request for funding this project has not been submitted to
|
---|
1207 | any other addressee. In case we submit such a request we will inform
|
---|
1208 | the Deutsche Forschungsgemeinschaft immediately. \\
|
---|
1209 |
|
---|
1210 | The corresponding persons (Vertrauensdozenten) at the
|
---|
1211 | Universit\"{a}t Dortmund (Prof.\ Dr.\ Gather) and at the Universit\"{a}t
|
---|
1212 | W\"{u}rzburg (Prof.\ Dr.\ G.\ Bringmann) have been informed about the
|
---|
1213 | submission of this proposal.
|
---|
1214 |
|
---|
1215 | \paragraph{7 Signatures (Unterschriften)}~\\
|
---|
1216 |
|
---|
1217 | \vspace{2.5 cm}
|
---|
1218 |
|
---|
1219 | \hfill
|
---|
1220 | \begin{minipage}[t]{6cm}
|
---|
1221 | W\"{u}rzburg,\\[3.0cm]
|
---|
1222 | \parbox[t]{6cm}{\hrulefill}\\
|
---|
1223 | \parbox[t]{6cm}{~\hfill Prof.\ Dr.\ Karl Mannheim\hfill~}\\
|
---|
1224 | \end{minipage}
|
---|
1225 | \hfill
|
---|
1226 | \begin{minipage}[t]{6cm}
|
---|
1227 | Dortmund,\\[3.0cm]
|
---|
1228 | \parbox[t]{6cm}{\hrulefill}\\
|
---|
1229 | \parbox[t]{6cm}{~\hfill Prof.\ Dr.\ Dr.\ Wolfgang Rhode\hfill~}\\
|
---|
1230 | \end{minipage}\hfill~
|
---|
1231 |
|
---|
1232 | \thispagestyle{empty}
|
---|
1233 | \newpage
|
---|
1234 | \mbox{}
|
---|
1235 | \thispagestyle{empty}
|
---|
1236 | \newpage
|
---|
1237 | \paragraph{8 List of appendices (Verzeichnis der Anlagen)}
|
---|
1238 |
|
---|
1239 | \begin{itemize}
|
---|
1240 | \item
|
---|
1241 | %Schriftenverzeichnis der Antragsteller seit dem Jahr 2000
|
---|
1242 | List of refereed publications of the applicants since 2000
|
---|
1243 | \item Appendix A: Chapter 4 in German
|
---|
1244 | \item CV of Karl Mannheim
|
---|
1245 | \item CV of Wolfgang Rhode
|
---|
1246 | \item Letter of Support from the MAGIC collaboration
|
---|
1247 | \item Letter of Support from Mets\"{a}hovi Radio Observatory
|
---|
1248 | \item Letter of Support from the IceCube collaboration
|
---|
1249 | \item Letter of Support from KVA optical telescope
|
---|
1250 | \item Email with offer from EMI for the PMs
|
---|
1251 | \end{itemize}
|
---|
1252 | \newpage
|
---|
1253 | \mbox{}
|
---|
1254 | \thispagestyle{empty}
|
---|
1255 | \newpage
|
---|
1256 |
|
---|
1257 | \appendix
|
---|
1258 | \germanTeX
|
---|
1259 | \section[4]{Beantragte Mittel}
|
---|
1260 |
|
---|
1261 | Die beantragten Mittel werden durch die Ausgaben f"ur die Kamera und
|
---|
1262 | die Datennahme dominiert. Wir beantragen eine F"orderung von drei Jahren.
|
---|
1263 |
|
---|
1264 | \subsection[4.1]{Personalkosten}
|
---|
1265 |
|
---|
1266 | F"ur diesen Zeitraum beantragen wir die Finanzierung von zwei Postdocs
|
---|
1267 | und zwei Doktoranden, jeweils einer in Dortmund und einer in W"urzburg
|
---|
1268 | (3\,x\,TV-L13). Mit den besetzten Stellen sollen die erw"ahnten Arbeiten
|
---|
1269 | zur Planung und zum Bau des Teleskops durchgef"uhrt werden. Zus"atzlich
|
---|
1270 | wird noch eine schwankende Zahl an Doktoranden und Diplomanden
|
---|
1271 | zur Verf"ugung stehen.
|
---|
1272 |
|
---|
1273 | Interessierte Kandidaten sind Dr.\ Thomas
|
---|
1274 | Bretz, Dr.\ dest.\ Daniela Dorner, Dr.\ dest.\ Kirsten M\"{u}nich,
|
---|
1275 | cand.\ phys.\ Michael Backes, cand.\ phys.\ Daniela Hadasch und cand.\
|
---|
1276 | phys.\ Dominik Neise.
|
---|
1277 |
|
---|
1278 | \subsection[4.2]{Wissenschaftliche Ger\"{a}te}
|
---|
1279 |
|
---|
1280 | Am Observatorio del Roque de los Muchachos (ORM), nahe dem MAGIC
|
---|
1281 | Teleskop, steht noch das ehemalige HEGRA-Teleskop (CT3) zur Verf"ugung.
|
---|
1282 | Es ist noch immer nutzbar und geh"ort jetzt der MAGIC Kollaboration.
|
---|
1283 | Au"serdem ist noch ein Container zur Unterbringung von Elektronik,
|
---|
1284 | sowie weiterer Platz im MAGIC-eignenen Haus vorhanden. Der Memorandum
|
---|
1285 | of Understanding der MAGIC-Kollaboration erlaubt uns den Betrieb des
|
---|
1286 | Teleskops als DWARF (see Anlage). F"ur Notfallsituationen steht die
|
---|
1287 | MAGIC Schichtmannschaft zur Verf"ugung.
|
---|
1288 |
|
---|
1289 | Um die angestrebte Sensitivit"at und Energieschwelle (fig.~\ref{sensitivity})
|
---|
1290 | in m"oglichgst kurzer Zeit zu erreichen, wurden die folgenden
|
---|
1291 | Komponenten ausgew"ahlt. Einzelheiten zu den Auswahlkriterien k"onnen
|
---|
1292 | im Kapitel~4 nachgelesen werden.\\
|
---|
1293 |
|
---|
1294 | {\bf Kamera}\dotfill 206.450,-\,\euro\\[-3ex]
|
---|
1295 | \begin{quote}
|
---|
1296 | F"ur eine Kamera mit 313 Pixel werden folgende Komponenten ben"otigt:\\
|
---|
1297 | \parbox[t]{1em}{~}\begin{minipage}[t]{0.6\textwidth}
|
---|
1298 | Photomultiplier R"ohre EMI\,9083B\hfill 220,-\,\euro\\
|
---|
1299 | Aktiver Spannungsteiler (EMI)\hfill 80,-\,\euro\\
|
---|
1300 | Hochspannungsversorgung und -kontrolle\hfill 300,-\,\euro\\
|
---|
1301 | Vorverst"arker\hfill 50,-\,\euro\\
|
---|
1302 | Ersatzteile (pauschal)\hfill 3000,-\,\euro\\
|
---|
1303 | \end{minipage}\\[-0.5ex]
|
---|
1304 | %For long-term observations, the stability of the camera is a major
|
---|
1305 | %criterion. To keep the systematic errors small, a good background
|
---|
1306 | %estimation is mandatory. The only possibility for a synchronous
|
---|
1307 | %determination of the background is the measurement from the night-sky
|
---|
1308 | %observed in the same field-of-view with the same instrument. To achieve
|
---|
1309 | %this, the observed position is moved out of the camera center which
|
---|
1310 | %allows the estimation of the background from positions symmetric with
|
---|
1311 | %respect to the camera center (so called Wobble mode). This observation
|
---|
1312 | %mode increases the sensitivity by a factor of $\sqrt{2}$, because
|
---|
1313 | %spending observation time for dedicated background observations becomes
|
---|
1314 | %obsolete, i.e.\ observation time for the source is doubled. This
|
---|
1315 | %ensures in addition a better time coverage of the observed sources.\\
|
---|
1316 | %A further increase in sensitivity can be achieved by better background
|
---|
1317 | %statistics from not only one but several independent positions for the
|
---|
1318 | %background estimation in the camera \citep{Lessard:2001}. To allow for
|
---|
1319 | %this the source position in Wobble mode should be shifted
|
---|
1320 | %$0.6^\circ-0.7^\circ$ out of the camera center.
|
---|
1321 | %
|
---|
1322 | %A camera completely containing the shower images of events in the energy
|
---|
1323 | %region of 1\,TeV-10\,TeV should have a diameter in the order of
|
---|
1324 | %5$^\circ$. To decrease the dependence of the measurements on the camera
|
---|
1325 | %geometry, a camera layout as symmetric as possible will be chosen.
|
---|
1326 | %Consequently a camera allowing to fulfill these requirements should be
|
---|
1327 | %round and have a diameter of $4.5^\circ-5.0^\circ$.
|
---|
1328 | %
|
---|
1329 | %Therefore a camera with 313 pixel camera (see fig.~\ref{camDWARF}) is
|
---|
1330 | %chosen. The camera will be built based on the experience with HEGRA and
|
---|
1331 | %MAGIC. 19\,mm diameter Photomultiplier Tubes (PM, EMI\,9083B/KFLA-UD)
|
---|
1332 | %will be bought, similar to the HEGRA type (EMI\,9083\,KFLA). They have
|
---|
1333 | %a quantum efficiency improved by 25\% (see fig.~\ref{qe}) and ensure a
|
---|
1334 | %granularity which is enough to guarantee good results even below the
|
---|
1335 | %energy threshold (flux peak energy). Each individual pixel has to be
|
---|
1336 | %equipped with a preamplifier, an active high-voltage supply and
|
---|
1337 | %control. The total expense for a single pixel will be in the order of
|
---|
1338 | %650,-\,\euro.
|
---|
1339 | %
|
---|
1340 | %All possibilities of borrowing one of the old HEGRA cameras for a
|
---|
1341 | %transition time have been probed and refused by the owners of the
|
---|
1342 | %cameras.
|
---|
1343 | %
|
---|
1344 | %At ETH~Z\"{u}rich currently test measurements are ongoing to prove the
|
---|
1345 | %ability, i.e.\ stability, aging, quantum efficiency, etc., of using
|
---|
1346 | %Geiger-mode APDs (GAPD) as photon detectors in the camera of a
|
---|
1347 | %Cherenkov telescope. The advantages are an extremely high quantum
|
---|
1348 | %efficiency ($>$50\%), easier gain stabilization and simplified
|
---|
1349 | %application compared to classical PMs. If these test measurements are
|
---|
1350 | %successfully finished until 8/2008, we consider to use GAPDs in favor
|
---|
1351 | %of classical PMs. The design of such a camera would take place at
|
---|
1352 | %University Dortmund in close collaboration with the experts from ETH.
|
---|
1353 | %The construction would also take place at the electronics workshop of
|
---|
1354 | %Dortmund.
|
---|
1355 | \end{quote}\vspace{3ex}
|
---|
1356 | \newpage
|
---|
1357 | {\bf Kameraaufh"angung und -geh"ause}\dotfill 7.500,-\,\euro\\[-3ex]
|
---|
1358 | \begin{quote}
|
---|
1359 | %For this setup the camera holding has to be redesigned. (1500,-\,\euro)
|
---|
1360 | %The camera chassis must be water tight and will be equipped with an
|
---|
1361 | %automatic lid, protecting the PMs at daytime. For further protection, a
|
---|
1362 | %plexi-glass window will be installed in front of the camera. By coating
|
---|
1363 | %this window with an anti-reflex layer of magnesium-fluoride, a gain in
|
---|
1364 | %transmission of 5\% is expected. Each PM will be equipped with a
|
---|
1365 | %light-guide (Winston cone) as developed by UC Davis and successfully in
|
---|
1366 | %operation in the MAGIC camera. (3000,-\,\euro\ for all Winston cones). The
|
---|
1367 | %current design will be improved by using a high reflectivity aluminized
|
---|
1368 | %Mylar mirror-foil, coated with a dialectical layer ($Si\,O_2$
|
---|
1369 | %alternated with Niobium Oxide), to reach a reflectivity in the order of
|
---|
1370 | %98\%. An electric and optical shielding of the individual PMs is
|
---|
1371 | %planned.
|
---|
1372 | %
|
---|
1373 | %In total a gain of $\sim$15\% in light-collection
|
---|
1374 | %efficiency compared to the old CT3 system can be achieved.
|
---|
1375 | \end{quote}%\vspace{1ex}
|
---|
1376 | {\bf Datanahme}\dotfill 61.035,-\,\euro\\[-3ex]
|
---|
1377 | \begin{quote}
|
---|
1378 | 313 Pixels\\
|
---|
1379 | \parbox[t]{1em}{~}\begin{minipage}[t]{0.6\textwidth}
|
---|
1380 | Auslese\hfill 95,-\,\euro\\
|
---|
1381 | Triggerelektronik\hfill 100,-\,\euro\\
|
---|
1382 | \end{minipage}\\[-0.5ex]
|
---|
1383 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
1384 | %For the data acquisition system a hardware readout based on an analog
|
---|
1385 | %ring buffer (Domino\ II/IV), currently developed for the MAGIC~II
|
---|
1386 | %readout, will be used \citep{Barcelo}. This technology allows to sample
|
---|
1387 | %the pulses with high frequencies and readout several channels with a
|
---|
1388 | %single Flash-ADC resulting in low costs. The low power consumption will
|
---|
1389 | %allow to include the digitization near the signal source making
|
---|
1390 | %the transfer of the analog signal obsolete. This results in less
|
---|
1391 | %pick-up noise and reduces the signal dispersion. By high sampling rates
|
---|
1392 | %(1.2\,GHz), additional information about the pulse shape can be
|
---|
1393 | %obtained. This increases the over-all sensitivity further, because the
|
---|
1394 | %short integration time allows for almost perfect suppression of noise
|
---|
1395 | %due to night-sky background photons. The estimated trigger-, i.e.\
|
---|
1396 | %readout-rate of the telescope is below 100\,Hz (HEGRA: $<$10\,Hz) which
|
---|
1397 | %allows to use a low-cost industrial solution for readout of the system,
|
---|
1398 | %like USB\,2.0.
|
---|
1399 | %
|
---|
1400 | %Current results obtained with the new 2\,GHz FADC system in the MAGIC
|
---|
1401 | %data acquisition show, that for a single telescope a sensitivity
|
---|
1402 | %improvement of 40\% with a fast FADC system is achievable \citep{Tescaro:2007}.
|
---|
1403 | %
|
---|
1404 | %Like for the HEGRA telescopes a simple multiplicity trigger is
|
---|
1405 | %sufficient, but also a simple neighbor-logic could be programmed (both
|
---|
1406 | %cases $\sim$100,-\,\euro/channel).
|
---|
1407 | %
|
---|
1408 | %Additional data reduction and preprocessing within the readout chain is
|
---|
1409 | %provided. Assuming conservatively a readout rate of 30\,Hz, the storage
|
---|
1410 | %space needed will be less than 250\,GB/month or 3\,TB/year. This amount
|
---|
1411 | %of data can easily be stored and processed by the W\"{u}rzburg
|
---|
1412 | %Datacenter (current capacity $>$80\,TB, $>$40\,CPUs).
|
---|
1413 | \end{quote}\vspace{3ex}
|
---|
1414 |
|
---|
1415 | {\bf Spiegel}\dotfill 15.000,-\,\euro\\[-3ex]
|
---|
1416 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
1417 | \begin{quote}
|
---|
1418 | %The existing mirrors will be replaced by new plastic mirrors currently
|
---|
1419 | %developed by Wolfgang Dr\"{o}ge's group. The cheap and light-weight
|
---|
1420 | %material has been formerly used for Winston cones in balloon
|
---|
1421 | %experiments. The mirrors are copied from a master and coated with a
|
---|
1422 | %reflecting and a protective material. Tests have given promising
|
---|
1423 | %results. By a change of the mirror geometry, the mirror area can be
|
---|
1424 | %increased from 8.5\,m$^2$ to 13\,m$^2$ (see picture~\ref{CT3} and
|
---|
1425 | %montage~\ref{DWARF}). This includes an increase of $\sim$10$\%$ per
|
---|
1426 | %mirror by using a hexagonal layout instead of a round one. A further
|
---|
1427 | %increase of the mirror area would require a reconstruction of parts of
|
---|
1428 | %the mount and will therefore be considered only in a later phase of the
|
---|
1429 | %experiment.
|
---|
1430 | %
|
---|
1431 | %If the current development of the plastic mirrors cannot be finished in
|
---|
1432 | %time, a re-machining of the old glass mirrors (8.5\,m$^2$) is possible
|
---|
1433 | %with high purity aluminum and quartz coating.
|
---|
1434 | %
|
---|
1435 | %In both cases the mirrors can be coated with the same high reflectivity
|
---|
1436 | %aluminized Mylar mirror-foil and a dialectical layer of $SiO_2$ as for
|
---|
1437 | %the Winston cones. By this, a gain in reflectivity of $\sim10\%$ is
|
---|
1438 | %achieved, see fig.~\ref{reflectivity} \citep{Fraunhofer}. Both
|
---|
1439 | %solutions would require the same expenses.
|
---|
1440 | %
|
---|
1441 | %To keep track of the alignment, reflectivity and optical quality of the
|
---|
1442 | %individual mirrors and the point-spread function of the total mirror
|
---|
1443 | %during long-term observations, the application of an automatic mirror
|
---|
1444 | %adjustment system, as developed by ETH~Z\"{u}rich and successfully
|
---|
1445 | %operated on the MAGIC telescope, is intended.
|
---|
1446 | \end{quote}%\vspace{3ex}
|
---|
1447 | {\bf Kalibrationssystem}\dotfill 9.650,-\,\euro\\[-3ex]
|
---|
1448 | \begin{quote}
|
---|
1449 | Einzelkomponenten\\
|
---|
1450 | \parbox[t]{1em}{~}\begin{minipage}[t]{0.6\textwidth}
|
---|
1451 | Absolute Lichtkalibration\hfill 2.000,-\,\euro\\
|
---|
1452 | Messung der Trigger Rate einzelner Pixel\hfill 3.000,-\,\euro\\
|
---|
1453 | Wetterstation\hfill 500,-\,\euro\\
|
---|
1454 | GPS gesteuerte Uhr\hfill 1.500,-\,\euro\\
|
---|
1455 | CCD Kameras mit Auslese\hfill 2.650,-\,\euro\\
|
---|
1456 | \end{minipage}\\[-0.5ex]
|
---|
1457 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
1458 | %For the absolute light calibration (gain-calibration) of the PMs a
|
---|
1459 | %calibration box, as successfully used in the MAGIC telescope, will be
|
---|
1460 | %produced.
|
---|
1461 | %
|
---|
1462 | %To ensure a homogeneous acceptance of the camera, essential for
|
---|
1463 | %Wobble mode observations, the trigger rate of the individual pixels
|
---|
1464 | %will be measured and controlled.
|
---|
1465 | %
|
---|
1466 | %For a correction of axis misalignments and possible deformations of the
|
---|
1467 | %structure (e.g.\ bending of camera holding masts) a pointing correction
|
---|
1468 | %algorithm will be applied, as used in the MAGIC tracking system. It is
|
---|
1469 | %calibrated by measurements of the reflection of bright guide stars on
|
---|
1470 | %the camera surface and ensures a pointing accuracy well below the pixel
|
---|
1471 | %diameter. Therefore a high sensitive low-cost video camera, as for
|
---|
1472 | %MAGIC\ I and~II, (300,-\,\euro\ camera, 600,-\,\euro\ optics,
|
---|
1473 | %300,-\,\euro\ housing, 250,-\,\euro\ frame grabber) will be installed.
|
---|
1474 | %
|
---|
1475 | %A second identical CCD camera for online monitoring (starguider) will
|
---|
1476 | %be bought.
|
---|
1477 | %
|
---|
1478 | %For an accurate tracking a GPS clock is necessary. The weather station
|
---|
1479 | %helps judging the data quality.
|
---|
1480 | %}\\[2ex]
|
---|
1481 | \end{quote}\vspace{3ex}
|
---|
1482 |
|
---|
1483 | {\bf Computing}\dotfill 12.000,-\,\euro\\[-3ex]
|
---|
1484 | \begin{quote}
|
---|
1485 | \parbox[t]{1em}{~}\begin{minipage}[t]{0.6\textwidth}
|
---|
1486 | Drei PCs\hfill 8.000,-\,\euro\\
|
---|
1487 | SATA RAID 3TB\hfill 4.000,-\,\euro\\
|
---|
1488 | \end{minipage}\\[-0.5ex]
|
---|
1489 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
1490 | %For on-site computing three standard PCs are needed ($\sim$8.000,-\,\euro).
|
---|
1491 | %This includes readout and storage, preprocessing and telescope control.
|
---|
1492 | %For safety reasons, a firewall is mandatory. For local cache-storage
|
---|
1493 | %and backup, two RAID\,5 SATA disk arrays with one Terabyte capacity
|
---|
1494 | %each will fulfill the requirement ($\sim$4.000,-\,\euro). The data will be
|
---|
1495 | %transmitted as soon as possible after data taking via Internet to the
|
---|
1496 | %W\"{u}rzburg Datacenter. Enough storage capacity and computing power
|
---|
1497 | %is available there and already reserved for this purpose.
|
---|
1498 | %
|
---|
1499 | %Monte Carlo production and storage will take place at University
|
---|
1500 | %Dortmund.%}\\[2ex]
|
---|
1501 | \end{quote}\vspace{3ex}
|
---|
1502 |
|
---|
1503 | {\bf Antrieb und Positionsauslese}\dotfill 17.500,-\,\euro\\[-3ex]
|
---|
1504 | \begin{quote}
|
---|
1505 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
1506 | %The present mount is used. Only a smaller investment for safety,
|
---|
1507 | %corrosion protection, cable ducts, etc. is needed (7.500,-\,\euro).
|
---|
1508 | %
|
---|
1509 | %Motors, shaft encoders and control electronics in the order of
|
---|
1510 | %10.000,-\,\euro\ have to be bought. The costs have been estimated with
|
---|
1511 | %the experience from building the MAGIC drive systems. The DWARF drive
|
---|
1512 | %system should allow for relatively fast repositioning for three
|
---|
1513 | %reasons: (i)~Fast movement might be mandatory for future ToO
|
---|
1514 | %observations. (ii)~Wobble mode observations will be done changing the
|
---|
1515 | %Wobble-position continuously (each 20\,min) for symmetry reasons.
|
---|
1516 | %(iii)~To ensure good time coverage of more than one source visible at
|
---|
1517 | %the same time, the observed source will be changed in constant time
|
---|
1518 | %intervals.
|
---|
1519 | %
|
---|
1520 | %For the drive system three 150\,Watt servo motors are intended to be bought. A
|
---|
1521 | %micro-controller based motion control unit (Siemens SPS L\,20) similar to
|
---|
1522 | %the one of the current MAGIC~II drive system will be used. For
|
---|
1523 | %communication with the readout-system, a standard Ethernet connection
|
---|
1524 | %based on the TCP/IP- and UDP-protocol will be setup.
|
---|
1525 | %}\\[2ex]
|
---|
1526 | \end{quote}%\vspace{3ex}
|
---|
1527 | %
|
---|
1528 | {\bf Sicherheit}\dotfill 4.000,-\,\euro\\[-3ex]
|
---|
1529 | \begin{quote}
|
---|
1530 | \parbox[t]{1em}{~}\begin{minipage}[t]{0.6\textwidth}
|
---|
1531 | Unterbrechungsfreie Stromversorgung (UPS)\hfill 2.000,-\,\euro\\
|
---|
1532 | Sicherheitszaun\hfill 2.000,-\,\euro\\
|
---|
1533 | \end{minipage}\\[-0.5ex]
|
---|
1534 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
1535 | %A UPS with 5\,kW-10\,kW will be
|
---|
1536 | %installed to protect the equipment against power cuts and ensure a safe
|
---|
1537 | %telescope position at the time of sunrise.
|
---|
1538 | %
|
---|
1539 | %For protection in case of robotic movement a fence will be
|
---|
1540 | %installed.%}\\[2ex]
|
---|
1541 | \end{quote}\vspace{3ex}
|
---|
1542 |
|
---|
1543 | {\bf Andere Ausgaben}\dotfill 7.500,-\,\euro\\[-3ex]
|
---|
1544 | \begin{quote}
|
---|
1545 | %\parbox[t]{1em}{~}\begin{minipage}[t]{0.6\textwidth}
|
---|
1546 | % Robotics\hfill 7.500,-\,\euro\\
|
---|
1547 | % \end{minipage}\\[-0.5ex]
|
---|
1548 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
1549 | F"ur den Betrieb in Fernsteuerung
|
---|
1550 | werden verschiedene fernbedienbare Komponenten, wie z.B.\
|
---|
1551 | Ethernet steuerbare Steckdosen und "Uberwachungselektronik, gekauft.
|
---|
1552 | \end{quote}
|
---|
1553 | \hspace*{0.66\textwidth}\hrulefill\\[0.5ex]
|
---|
1554 | \hspace*{0.66\textwidth}\hspace{0.5ex}\hfill Sum 4.2:\hfill{\bf
|
---|
1555 | 341.135,-\,\euro}\hfill\hspace*{0pt}\\[-1ex]
|
---|
1556 | \hspace*{0.66\textwidth}\hrulefill\\[-1.9ex]
|
---|
1557 | \hspace*{0.66\textwidth}\hrulefill\\
|
---|
1558 |
|
---|
1559 | \subsection[4.3]{Verbrauchsmaterial}
|
---|
1560 |
|
---|
1561 | \begin{quote}
|
---|
1562 | % \parbox[t]{1em}{~}\begin{minipage}[t]{0.9\textwidth}
|
---|
1563 | 10 LTO\,4 B"ander (8\,TB)\dotfill 750,-\,\euro\\
|
---|
1564 | Verbrauchsgegenst"ande (pauschal): Werkzeug und Meterialien\dotfill 10.000,-\,\euro
|
---|
1565 | % \end{minipage}\\[-0.5ex]
|
---|
1566 | \end{quote}
|
---|
1567 |
|
---|
1568 | \hspace*{0.66\textwidth}\hrulefill\\[0.5ex]
|
---|
1569 | \hspace*{0.66\textwidth}\hspace{0.5ex}\hfill Sum 4.3:\hfill{\bf
|
---|
1570 | 10.750,-\,\euro}\hfill\hspace*{0pt}\\[-1ex]
|
---|
1571 | \hspace*{0.66\textwidth}\hrulefill\\[-1.9ex]
|
---|
1572 | \hspace*{0.66\textwidth}\hrulefill\\
|
---|
1573 |
|
---|
1574 | \subsection[4.4]{Reisen}
|
---|
1575 | Die hohen Reisekosten sind in der engen Zusammenarbeit zwischen
|
---|
1576 | Dortmund und W"urzburg, sowie den notwendigen Aufenthalten in La Palma
|
---|
1577 | begr"undet.\\[-2ex]
|
---|
1578 |
|
---|
1579 | \begin{quote}
|
---|
1580 | %\parbox[t]{1em}{~}\parbox[t]{0.955\textwidth}{
|
---|
1581 | Jedes Jahr sollte ein erfahrenes Gruppenmitglied aus Dortmund und
|
---|
1582 | W"urzburg den Status des Projektes bei einer internationalen Konferenz
|
---|
1583 | vorstellen:\\
|
---|
1584 | 2 x 3\,Jahre x 1.500,-\,\euro\dotfill 9.000,-\,\euro\\[-2ex]
|
---|
1585 |
|
---|
1586 | Teilnahme am MAGIC Kollaborationstreffen (zweimal j"ahrlich):\\
|
---|
1587 | 2 x 3\,Jahre x 1.000,-\,\euro\dotfill 6.000,-\,\euro\\[-2ex]
|
---|
1588 |
|
---|
1589 | Austausch von Doktoranden zwischen W\"{u}rzburg and Dortmund:\\
|
---|
1590 | 1\,Student x 1\,Woche x 24 (alle sechs Wochen) x 800,-\,\euro\dotfill
|
---|
1591 | 19.200,-\,\euro\\[-2ex]
|
---|
1592 |
|
---|
1593 | Zum Aufbau des Teleskops vor Ort werden sind Ausgaben n"otig:\\
|
---|
1594 | 4 x 2\,Wochen auf La Palma x 2\,Personen x 1.800,-\,\euro\dotfill
|
---|
1595 | 28.800,-\,\euro
|
---|
1596 | %}
|
---|
1597 | \end{quote}
|
---|
1598 |
|
---|
1599 | \hspace*{0.66\textwidth}\hrulefill\\[0.5ex]
|
---|
1600 | \hspace*{0.66\textwidth}\hspace{0.5ex}\hfill Sum 4.4:\hfill{\bf
|
---|
1601 | 63.000,-\,\euro}\hfill\hspace*{0pt}\\[-1ex]
|
---|
1602 | \hspace*{0.66\textwidth}\hrulefill\\[-1.9ex]
|
---|
1603 | \hspace*{0.66\textwidth}\hrulefill\\
|
---|
1604 |
|
---|
1605 |
|
---|
1606 | \subsection[4.5]{Publikationskosten}
|
---|
1607 | Werden von den beantragenden Universit"aten "ubernommen.
|
---|
1608 |
|
---|
1609 |
|
---|
1610 | \subsection[4.6]{Sonstige Kosten}
|
---|
1611 | \begin{quote}
|
---|
1612 | Euro-Container (zum Versandt der Spiegel)\dotfill 5.000,-\,\euro\\
|
---|
1613 | Transport\dotfill 15.000,-\,\euro\\
|
---|
1614 | Abbau (wird von den Antragstellern "ubernommen)\dotfill n/a
|
---|
1615 | \end{quote}
|
---|
1616 |
|
---|
1617 | \hspace*{0.66\textwidth}\hrulefill\\[0.5ex]
|
---|
1618 | \hspace*{0.66\textwidth}\hspace{0.5ex}\hfill Sum 4.6:\hfill{\bf
|
---|
1619 | 20.000,-\,\euro}\hfill\hspace*{0pt}\\[-1ex]
|
---|
1620 | \hspace*{0.66\textwidth}\hrulefill\\[-1.9ex]
|
---|
1621 | \hspace*{0.66\textwidth}\hrulefill\\
|
---|
1622 |
|
---|
1623 | \newpage
|
---|
1624 | \thispagestyle{empty}
|
---|
1625 | \mbox{}
|
---|
1626 | \newpage
|
---|
1627 |
|
---|
1628 | \originalTeX
|
---|
1629 |
|
---|
1630 | %(References of our groups are marked by an asterix *)
|
---|
1631 | \bibliography{application}
|
---|
1632 | \bibliographystyle{plainnat}
|
---|
1633 | %\bibliographystyle{alpha}
|
---|
1634 | %\bibliographystyle{plain}
|
---|
1635 |
|
---|
1636 | \end{document}
|
---|