Quantum technology is approaching a level of maturity, recently demonstrated in space-borne experiments and in-field measurements, which would allow for adoption by non-specialist users. Parallel advancements made in microprocessor-based electronics and database software can be combined to create robust, versatile and modular experimental monitoring systems. Here, we describe a monitoring network used across a number of cold atom laboratories with a shared laser system. The ability to diagnose malfunction, unexpected or unintended behavior and passively collect data for key experimental parameters, such as vacuum chamber pressure, laser beam power, or resistances of important conductors, significantly reduces debugging time. This allows for efficient control over a number of experiments and remote control when access is limited.

量子技术正在接近成熟水平，最近在太空实验和现场测量中得到证明，这将允许非专业用户采用。在基于微处理器的电子设备和数据库软件方面取得的平行进步可以结合起来创建强大的、多功能的和模块化的实验监测系统。在这里，我们描述了一个跨多个冷原子实验室使用的共享激光系统的监控网络。诊断故障、意外或意外行为并被动收集关键实验参数数据的能力，例如真空室压力、激光束功率或重要导体的电阻，显着缩短了调试时间。这允许在访问受限时有效控制大量实验和远程控制。