This paper studies the problem of deciding on the absence (i.e., null hypothesis, $\mathcal{H}_0$) or presence (i.e., alternative hypothesis, $\mathcal{H}_1$) of an unknown signal embedded in the received signal in a multiple-input, multiple-output (MIMO) receiver, employing 1-bit quantization. The originality of our solution lies in quantizing the received signal by an adapted 1-bit window comparator, rather than a traditional 1-bit quantizer. This enables us to divide the space of observed binary sequences into two typical sets (w.r.t. the distribution of the no. of 1's in a sequence) asymptotically, where the first set corresponds to $\mathcal{H}_0$ and the second to $\mathcal{H}_1$. As a result, we reduce the detection problem to determining the highly probable set for an observed sequence. Thus, a very low-complexity binary hypothesis detector is proposed and its probability of detection is given. To show the high efficacy of the proposed 1-bit receiver structure, we consider two wireless applications; jamming detection in a massive MIMO system, and probing a non-stationary low-power transmitter in a wireless sensor network (WSN), assuming unknown Rayleigh-fading channels. Compared with an unquantized system employing a chi-square test, it is shown that the performance loss can be roughly as large as $10\%$ in massive MIMO and this gap diminishes as sequence length or/and jamming power increases. For WSN, we show that compared with an unquantized system, the performance gap becomes smaller when the observation interval is extended over a few symbols.
翻译:本文研究了在多输入、多输出接收器中嵌入的接收信号中的未知信号的缺失( 即, 无效假设, $\mathcal{H ⁇ 0$) 或存在( 替代假设, $\mathcal{H ⁇ 1$) 的问题。 我们的解决方案的最初性能在于将接收信号通过一个经调整的 1 位窗口比较器而不是传统的 1 位量量计进行量化。 这使我们能够将观测到的二进制序列的空间分为两种典型的( 替代假设, $\ mathcal{H ⁇ 1$1$ 美元) 。 在多个输入器中, 第一个设置相当于 $\ mathcal( H ⁇ 0$), 第二个是 macentralcal 等值。 因此, 我们减少探测问题, 确定一个被观察到的序列的高度概率设定。 因此, 一个非常低的二进制假设检测器检测器被提出来, 其探测的概率是两个。 将一个高的系统显示, 正在测试中, 一个高存储的机级测试系统显示, 一个高的机级测试系统的功能, 一个是 10进级测试, 一个测试, 一个测试的系统是 一个高性测试, 一个测试, 一个系统的轨道, 一个测试, 当我们作为我们 的轨道的轨道的轨道的轨道的测试, 一个在一个 10°级变变变。