Update README.md

README.md

@@ -48,8 +48,10 @@ print(tokenizer.decode(outputs[0], skip_special_tokens=True))
 
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 # examples
-{context}: propagation mechanism with line-of-sight, \ufb01rst-order re\ufb02ec-tions and scattering becoming much more dominant. Thismeans shadowing will have severe detrimental effects on theaverage received power. Indeed, channel models developedfor millimeter-wave include a third state, in addition toline-of-sight and non-line-of-sight, to explicitly model an out-age event when received power is too weak to establish alink [3]. Although adaptive beam steering techniques can
-{diaogues}: Speaker 1: How does shadowing affect millimeter-wave channel models?\nSpeaker 2: Shadowing has severe detrimental effects on the average received power and can cause an outage event, leading to a third state in channel models to model this event.\nSpeaker 1: So, what are some techniques that can be used to mitigate the effects of shadowing?\nSpeaker 2: Well, as I mentioned earlier, adaptive beam steering is one approach. By constantly adjusting the direction of the transmit and receive beams, it is possible to maintain a strong enough signal to overcome the effects of shadowing.\nSpeaker 1: That's interesting. But in a highly dynamic environment, like a crowded city, would this technique still be effective?\nSpeaker 2: Good point. In that case, another technique that can be used is diversity reception. By using multiple antennas and taking advantage of the different paths that signals can take, it is possible to improve the signal quality and overcome the effects of shadowing.\nSpeaker 1: Ah, I see. And how does this compare to traditional cellular systems where shadowing is also a concern?\nSpeaker 2: That's a great question. In traditional cellular systems, shadowing is not as severe due to the lower frequencies used. However, in millimeter-wave systems, the wavelength is much smaller, making them more susceptible to shadowing and requiring these specialized techniques for mitigation.\nSpeaker 1: I see. Well, it looks like careful consideration and implementation of these techniques will be crucial for successful millimeter-wave communication. Thank you for explaining this to me.\nSpeaker 2: ###
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+{context}: A New CCn Inverter Circuit For AMLCD Panels Results In Significantly Higher Efficiency And Brightness Mehmet K. Nalbant Linfinity Microelectronics 11861 Western Ave., Garden Grove, CA 92641 Tel: (714) 898-8121 Fax: (714) 893-2570 Abstract - The paper will discuss a new CCFL inverter that is based on a new control technique named the Current Synchronous Zero Voltage Switching (CS-ZVS) topology. This topology enables the design of very eficient dimmable CCFL inverter
+{diaogues}: Speaker 1: What is the name of the new control technique used in the CCFL inverter?\nSpeaker 2: The new control technique is called Current Synchronous Zero Voltage Switching (CS-ZVS) topology.\nSpeaker 1: Can you tell me more about the CS-ZVS topology?\nSpeaker 2: Sure! The CS-ZVS topology is a new control technique that allows for the design of highly efficient and dimmable CCFL inverters.\nSpeaker 1: That sounds impressive. How does it achieve higher efficiency and brightness?\nSpeaker 2: Well, the CS-ZVS topology synchronizes the switching of the inverter with the current flow, resulting in lower losses and improved performance.\nSpeaker 1: I see. So, is this new CCFL inverter already available in the market?\nSpeaker 2: Yes, it is. It was developed by Linfinity Microelectronics and is currently being used in AMLCD panels to improve their efficiency and brightness.\nSpeaker 1: That's amazing. I'm sure this new inverter will be very popular in the market.\nSpeaker 2: ###
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 ### **License**