![Figure 9 from A 1024-QAM capable WLAN receiver with −56.3 dB image rejection ratio using self-calibration technique | Semantic Scholar Figure 9 from A 1024-QAM capable WLAN receiver with −56.3 dB image rejection ratio using self-calibration technique | Semantic Scholar](https://d3i71xaburhd42.cloudfront.net/64cbe0f087c8aa03ce0d9d0f4bede5f812c3928e/4-Figure9-1.png)
Figure 9 from A 1024-QAM capable WLAN receiver with −56.3 dB image rejection ratio using self-calibration technique | Semantic Scholar
Single-channel 200 Gbit/s, 10 Gsymbol/s-1024 QAM injection-locked coherent transmission over 160 km with a pilot-assisted adaptive equalizer
Single-channel 200 Gbit/s, 10 Gsymbol/s-1024 QAM injection-locked coherent transmission over 160 km with a pilot-assisted adaptive equalizer
![Figure 4 from Transmission performance of OFDM with 1024-QAM in the presence of EVM degradation | Semantic Scholar Figure 4 from Transmission performance of OFDM with 1024-QAM in the presence of EVM degradation | Semantic Scholar](https://d3i71xaburhd42.cloudfront.net/5b00e858d39ef8dcd9a211a7ce999c5146bb79fc/3-Figure4-1.png)
Figure 4 from Transmission performance of OFDM with 1024-QAM in the presence of EVM degradation | Semantic Scholar
Transmission Performance of an OFDM-Based Higher-Order Modulation Scheme in Multipath Fading Channels
![Figure 2 from Performance evaluation of OFDM-based 256- and 1024-QAM in multipath fading propagation conditions | Semantic Scholar Figure 2 from Performance evaluation of OFDM-based 256- and 1024-QAM in multipath fading propagation conditions | Semantic Scholar](https://d3i71xaburhd42.cloudfront.net/0a8627cc7adde94b70d5d9f73f9dea99193795f0/2-Figure2-1.png)