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 {"tstamp": 1722713963.0033, "task_type": "retrieval", "type": "chat", "model": "sentence-transformers/all-MiniLM-L6-v2", "gen_params": {}, "start": 1722713960.7698, "finish": 1722713963.0033, "ip": "", "conv_id": "c3e2c5ddf706414b9041d32da88fc851", "model_name": "sentence-transformers/all-MiniLM-L6-v2", "prompt": "Which test was devised to determine whether robots can think?", "output": [["Which test was devised to determine whether robots can think?", "History of robots\n\nIt features a female humanoid automaton standing by a basin filled with water.When the user pulls the lever, the water drains and the female automaton refills the basin. Furthermore, he created a robotic musical band. According to Mark Rosheim, unlike Greek designs Arab automata worked with dramatic illusion and manipulated the human perception for practical application. The segmental gears described in The Book of Knowledge of Ingenious Mechanical Devices, published by Al-Jazari shortly before his death in 1206, appeared 100 years later in the most advanced European clocks. Al-Jazari also published instructions on the construction of humanoid automata. The first water clocks modeled on Arabic designs were constructed in Europe about 1000 CE, possibly on the basis of the information that was transmitted during Muslim-Christian contact in Sicily and Spain. Among the first recorded European water clocks is that of Gerbert of Aurillac, built in 985 CE. Hero's works on automata were translated into Latin amid the 12th century Renaissance. The early 13th-century artist-engineer Villard de Honnecourt sketched plans for several automata. "]], "corpus": "wikipedia"}
 {"tstamp": 1722713996.4933, "task_type": "retrieval", "type": "chat", "model": "nomic-ai/nomic-embed-text-v1.5", "gen_params": {}, "start": 1722713994.3338, "finish": 1722713996.4933, "ip": "", "conv_id": "1b7f253a01714dd4a3f96e128a1b3aed", "model_name": "nomic-ai/nomic-embed-text-v1.5", "prompt": "Find me a planet near α 23h 06m 29.368s and δ −05° 02′ 29.04″ that could be habitable.", "output": [["Find me a planet near α 23h 06m 29.368s and δ −05° 02′ 29.04″ that could be habitable.", "Habitable zone\n\nGliese 163 c, discovered in September 2012 in orbit around the red dwarf Gliese 163 is located 49 light years from Earth. The planet has 6.9 Earth masses and 1.8–2.4 Earth radii, and with its close orbit receives 40 percent more stellar radiation than Earth, leading to surface temperatures of about ° C. HD 40307 g, a candidate planet tentatively discovered in November 2012, is in the circumstellar habitable zone of HD 40307. In December 2012, Tau Ceti e and Tau Ceti f were found in the circumstellar habitable zone of Tau Ceti, a Sun-like star 12 light years away. Although more massive than Earth, they are among the least massive planets found to date orbiting in the habitable zone; however, Tau Ceti f, like HD 85512 b, did not fit the new circumstellar habitable zone criteria established by the 2013 Kopparapu study. It is now considered as uninhabitable.\nNear Earth-sized planets and Solar analogs\nRecent discoveries have uncovered planets that are thought to be similar in size or mass to Earth. \"Earth-sized\" ranges are typically defined by mass. The lower range used in many definitions of the super-Earth class is 1.9 Earth masses; likewise, sub-Earths range up to the size of Venus (~0.815 Earth masses). An upper limit of 1.5 Earth radii is also considered, given that above  the average planet density rapidly decreases with increasing radius, indicating these planets have a significant fraction of volatiles by volume overlying a rocky core. A genuinely Earth-like planet – an Earth analog or \"Earth twin\" – would need to meet many conditions beyond size and mass; such properties are not observable using current technology."]], "corpus": "wikipedia"}
 {"tstamp": 1722713996.4933, "task_type": "retrieval", "type": "chat", "model": "mixedbread-ai/mxbai-embed-large-v1", "gen_params": {}, "start": 1722713994.3338, "finish": 1722713996.4933, "ip": "", "conv_id": "acef99acc74e4949859b4bbf9fe8ac3c", "model_name": "mixedbread-ai/mxbai-embed-large-v1", "prompt": "Find me a planet near α 23h 06m 29.368s and δ −05° 02′ 29.04″ that could be habitable.", "output": [["Find me a planet near α 23h 06m 29.368s and δ −05° 02′ 29.04″ that could be habitable.", "Habitable zone\n\nK2-18b is an exoplanet 124 light-years away, orbiting in the habitable zone of the K2-18, a red dwarf. This planet is significant for water vapor found in its atmosphere; this was announced on September 17, 2019.\nIn September 2020, astronomers identified 24 superhabitable planet (planets better than Earth) contenders, from among more than 4000 confirmed exoplanets at present, based on astrophysical parameters, as well as the natural history of known life forms on the Earth.\nHabitability outside the HZ\nLiquid-water environments have been found to exist in the absence of atmospheric pressure and at temperatures outside the HZ temperature range. For example, Saturn's moons Titan and Enceladus and Jupiter's moons Europa and Ganymede, all of which are outside the habitable zone, may hold large volumes of liquid water in subsurface oceans.\nOutside the HZ, tidal heating and radioactive decay are two possible heat sources that could contribute to the existence of liquid water. Abbot and Switzer (2011) put forward the possibility that subsurface water could exist on rogue planets as a result of radioactive decay-based heating and insulation by a thick surface layer of ice.\nWith some theorising that life on Earth may have actually originated in stable, subsurface habitats, it has been suggested that it may be common for wet subsurface extraterrestrial habitats such as these to 'teem with life'. On Earth itself, living organisms may be found more than  below the surface."]], "corpus": "wikipedia"}
+{"tstamp": 1722714645.6073, "task_type": "retrieval", "type": "chat", "model": "mixedbread-ai/mxbai-embed-large-v1", "gen_params": {}, "start": 1722714643.428, "finish": 1722714645.6073, "ip": "", "conv_id": "89142b20ef724b66804b266d1ea52920", "model_name": "mixedbread-ai/mxbai-embed-large-v1", "prompt": "Koliko je dva plus dva puta dva", "output": [["Koliko je dva plus dva puta dva", "Marija Šerifović\n\n2021-present: Dolazi ljubav During March 2022, Šerifović held five concerts in Banja Luka, Zagreb and Belgrade under the title Druga strana ploče Vol.3. The one in Zagreb was held to an audience of 10,000 people. In late December 2022, she released the single \"Dobar Vam dan\", which scored over million views in the first 24 hours. On 6 October 2023, Šerifović released her sixth studio album, titled Dolazi ljubav, under IDJTunes.\nŠerifović made a guest appearance on the Serbian show Kec na jedanaest on 15 October where she spoke about the album; she revealed how much love and emotions she put in while recording the songs. She also shared that two of the album's songs, \"Pola sunca\", featuring Matija Cvek which was also released as a single on 6 October 2023 and \"Drugačija\" were its highlights. The song was very commercially successful, peaking at number three on Billboard Croatia Songs for the week ending 21 October 2023.\nLegacy of \"Molitva\"\nIn May 2007, Serbian magazine Nedeljnik highlighted that Šerifović focused her Eurovision performance on vocal delivery rather than on spectacle, which is often linked to Eurovision entries, citing her quote: \"I like to hear music, not to watch it\". Furthermore, the article compared her international success to those of tennis players Ana Ivanovic, Jelena Janković and Novak Djokovic.\nIn 2010, The Eurovision Times declared \"Molitva\" as the third best Eurovision entry of all time. Moreover, in 2016, Special Broadcasting Service ranked Šerifović among the top ten most deserving winners of the Eurovision. In 2019, \"Molitva\" was also placed at number ten on The Independent's listing of Eurovision winners."]], "corpus": "wikipedia"}
+{"tstamp": 1722714645.6073, "task_type": "retrieval", "type": "chat", "model": "intfloat/multilingual-e5-large-instruct", "gen_params": {}, "start": 1722714643.428, "finish": 1722714645.6073, "ip": "", "conv_id": "c746c191c60d44b2b9cb2f0ff6a77919", "model_name": "intfloat/multilingual-e5-large-instruct", "prompt": "Koliko je dva plus dva puta dva", "output": [["Koliko je dva plus dva puta dva", "Nth root\n\n3  4\n/\n\\/  01 52.27 56          (Results)    (Explanations)\n01                   x = 1        10·1·0·1 + 10·2·0·1     ≤      1   <   10·1·0·2   + 10·2·0·2\n01                   y = 1        y = 10·1·0·1   + 10·2·0·1   =  1 +    0   =     1\n00 52                x = 2        10·1·1·2 + 10·2·1·2     ≤     52   <   10·1·1·3   + 10·2·1·3\n00 44                y = 44       y = 10·1·1·2   + 10·2·1·2   =  4 +   40   =    44\n08 27             x = 3        10·1·12·3 + 10·2·12·3   ≤    827   <   10·1·12·4  + 10·2·12·4\n07 29             y = 729      y = 10·1·12·3  + 10·2·12·3  =  9 +  720   =   729\n98 56          x = 4        10·1·123·4 + 10·2·123·4 ≤   9856   <   10·1·123·5 + 10·2·123·5\n98 56          y = 9856     y = 10·1·123·4 + 10·2·123·4 = 16 + 9840   =  9856\n00 00\nAlgorithm terminates: Answer is 12.34"]], "corpus": "wikipedia"}