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n. pl. mi·sos
A thick fermented paste made of cooked soybeans, salt, and often rice or barley, and used especially in making soups and sauces.

[Japanese, from Old Japanese; perhaps akin to Korean meju, dried brick of fermented soybeans.]


(Cookery) a thick brown salty paste made from soya beans, used to flavour savoury dishes, esp soups
[from Japanese]


(ˈmi soʊ)

a fermented paste of soybeans, salt, and often rice or barley, used esp. to flavor soups and sauces.
[1720–30; < Japanese]


a combining form meaning “hate,” with the object of hatred specified by the following element: misogamy. Compare mis-2.
[< Greek, comb. form of mīseîn to hate, mîsos hatred]


A variety of pastes made from fermented soya beans and grains. Used as a flavoring in Japanese cooking.
ThesaurusAntonymsRelated WordsSynonymsLegend:
Noun1.miso - a thick paste made from fermented soybeans and barley or rice malt; used in Japanese cooking to make soups or sauces
paste, spread - a tasty mixture to be spread on bread or crackers or used in preparing other dishes
Nihon, Nippon, Japan - a constitutional monarchy occupying the Japanese Archipelago; a world leader in electronics and automobile manufacture and ship building
References in periodicals archive ?
has announced at Mobile World Congress that Sprint has purchased 5G-ready massive MIMO solutions from Samsung, which includes deployment of Samsung's latest MIMO technology solutions on Sprint's 2.
MU-MIMO is the next evolution from single-user MIMO (SU-MIMO), which is generally referred to as MIMO.
During field testing in Suwon, Massive MIMO Samsung radios, equipped with vertical and horizontal beam-forming technology, reached peak speeds of 330 Mbps per channel using a 20 MHz channel of 2.
Following the launch in Japan of NEC's 4x4 MIMO LTE-A mobile router by UQ Communications earlier this year, we continue to build on the success of GDM7243Q, and are now the key enabler for OEMs looking for high performing 4x4 MIMO LTE-A chips.
For proportionally high throughput in according to the number of antenna, in contrast with the conventional MIMO systems using a few antennas, the massive MIMO system using large scale antenna is emerging [8-11].
There are several techniques to further improve the detection performance of MIMO radars, significant gain in range resolution can be achieved by using a step-frequency approach during transmission (Gurbuz et al 2009, stoica et al 2007, yoon et al 2009, petropulu et al 2012).
While the promises of MIMO technology for boosting data rates and improving service to the industry are enticing, the challenges of implementing multiple antennas within a compact smartphone are immense.
Their topics include MIMO detection methods, precoding for MIMO, MIMO optimized for single-carrier frequency-domain equalization, frequency-domain packet combining techniques for ultrawide band, link and system level simulation for MIMO, and physical-layer network coding with multiple-antenna relays.
Massive MIMO, a relatively new concept in 5G communications, addresses capacity and energy challenges facing next-generation communications systems.
In this paper, we propose a new configuration of the LTE 13 band MIMO antenna where antenna elements are separately located on the top and bottom portions of a mobile handset.
In MIMO transmission, if antennas are well separated, the signals at different antennas experience independent fading in a dispersal environment.