“…In terms of power amplifiers, Envelope Tracking leverages the development of the Doherty Power Amplifier (DPA) to enhance both accuracy and performance. Notably, the DPA offers an advantage by maintaining precision under high-power conditions [5]. However, due to its manufacturing process, it is unsuitable for applications such as FM, FSK, and PSK.…”
In this research paper, we will delve into a type of circuit known as a power amplifier. This circuit is designed to operate at two frequencies, allowing it to perform tasks at each frequency. The main goals of the design are to separate signals and ensure proper operation of the circuit in different modes. One notable feature of this power amplifier is its ability to work without any distortion, especially when both frequencies are used simultaneously. Achieving this has been made possible by combining a method that ensures signal termination with a strategy that enables their separation. To evaluate its performance, we conducted computer simulations as tests using both large signals. The findings indicate a 10.2 decibel increase in amplification, with an output power of 41.2 decibels measured in milliwatts (dBm) and an overall power efficiency of 40.2% at a frequency of 1.8 gigahertz. Furthermore, our research reveals that the suppression of signals for the 1.8 GHz band is reduced by 49 decibels compared to the original signal, while for the 2.6 GHz band, almost all traces of the second harmonic signal are completely eliminated. In addition, we propose a circuit that mitigates mixing outcomes and enhances linearity performance. The EDA software, Path Wave EM Design, is used for simulation purposes.
“…In terms of power amplifiers, Envelope Tracking leverages the development of the Doherty Power Amplifier (DPA) to enhance both accuracy and performance. Notably, the DPA offers an advantage by maintaining precision under high-power conditions [5]. However, due to its manufacturing process, it is unsuitable for applications such as FM, FSK, and PSK.…”
In this research paper, we will delve into a type of circuit known as a power amplifier. This circuit is designed to operate at two frequencies, allowing it to perform tasks at each frequency. The main goals of the design are to separate signals and ensure proper operation of the circuit in different modes. One notable feature of this power amplifier is its ability to work without any distortion, especially when both frequencies are used simultaneously. Achieving this has been made possible by combining a method that ensures signal termination with a strategy that enables their separation. To evaluate its performance, we conducted computer simulations as tests using both large signals. The findings indicate a 10.2 decibel increase in amplification, with an output power of 41.2 decibels measured in milliwatts (dBm) and an overall power efficiency of 40.2% at a frequency of 1.8 gigahertz. Furthermore, our research reveals that the suppression of signals for the 1.8 GHz band is reduced by 49 decibels compared to the original signal, while for the 2.6 GHz band, almost all traces of the second harmonic signal are completely eliminated. In addition, we propose a circuit that mitigates mixing outcomes and enhances linearity performance. The EDA software, Path Wave EM Design, is used for simulation purposes.
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