RTP – 媒体中心

Meet the R&S RTP Oscillscope

The R&S RTP is the most versatile multi-purpose oscilloscope.

How does high update rate help? RTP - see the difference

Benefits from the RTP oscillscopes, offering the fastest update rate of maximum 750,000 waveforms/s.

Isolate signal details with precise digital trigger. See the difference

RTP oscilloscopes can trigger on signals as small as 1/1000th of a vertical division thanks to digital triggering and adjustable hysteresis.

Quickly access your favourite tools. RTP - see the difference

Access your favourite scope functions most quickly via the toolbar.

Superior user experience. RTP - see the difference

Learn how easy it is to organize your waveforms and results with the RTP oscilloscope.

Serial bus decoding. RTP - see the difference

The 16 digital channels of the MSO option extend the measurement resources of the RTP. Use them for protocol-based triggering and decoding of low-speed interfaces such as I2C, SPI, MIL1553 or MIPI RFFE.

Compensate signal losses in real-time. RTP - see the difference

Compensate signal losses from test fixtures or cables in real-time.

Powerful spectrum and spectrogram. RTP - see the difference

Use the accuracy of the RTP for the analysis of wide-band RF signals.

Trigger on Zones in real-time. RTP - see the difference

The RTP's Zone trigger allowes as the only oscilloscope in the world to isolate events in the time and the frequency domain.

Automated measurements. RTP - see the difference

The RTP offers of more than 90 automated measurements, with statistical analysis and histogram and track display for data visualization. Learn to use it most easily.

Accelerate your EMI debugging. RTP - see the difference

See on our debugging example how to use the powerful spectrum analysis with log display, peak list and limit lines for visualizing and evaluating the EMI emission.

Differential signal math in real-time. RTP - see the difference

Benefit from differential and common mode signals beeing calculated in real-time.

相位相参多通道脉冲分析

可扩展且易于配置的雷达/电子战系统解决方案，能够准确执行多个脉冲信号的相位相参分析。

使用罗德与施瓦茨示波器进行高级抖动分析

基于信号模型的创新抖动分解算法

使用罗德与施瓦茨示波器进行时域反射 (TDR)/时域传输 (TDT) 分析

阻抗和传输损耗测量

脉冲信号能量测量

了解如何使用高级数学运算功能测量脉冲正弦波信号的能量。

针对积分数学波形的高级校正功能

了解如何使用高级数学运算功能消除积分数学波形中的 1/f 噪声，以便分析正弦或脉冲信号。

用于射频信号分析的 I/Q 模式

通过下变频转换示波器的射频信号，并借助 R&S®VSE 软件或外部工具使用获得的 IQ 样本进行进一步分析。

77 GHz 汽车电子雷达（第 1 部分）

详细了解汽车电子雷达设备的基本测试装置，包括 RTP 高性能示波器。

77 GHz 汽车电子雷达（第 2 部分）

针对变频器和其他装置组件实时去嵌。

77 GHz 汽车电子雷达（第 3 部分）

使用内置示波器功能解调雷达脉冲。

77 GHz 汽车电子雷达（第 4 部分）

针对多个天线信号执行相位相参测量。

Clock and LO components in 5G base stations (part 2/3)

Learn how to verify the performance of RF sampling clock generator / jitter attenuator with low noise signal generator and high-performance oscilloscope.

借助实时去嵌功能调试 USB 3.1 接口

如何针对 USB 3.1 Gen1 设备执行实时去嵌。

分析宽带脉冲射频信号

如何分析脉冲射频信号的基础参数。

电源完整性调试

配合使用电源完整性探头和高性能示波器。

实时去嵌

优点和优势

多个宽带射频信号的延时分析

分析常用于测向等应用的多个射频信号

DDR3 信号完整性调试

如何针对 DDR3 设备执行信号完整性调试。

信号完整性调试

使用 USB 3.1 Gen1 设备进行展示。

FFT 和瀑布图

轻松配置频域分析

通过区域触发来触发频域

独特的触发功能

分析复杂的雷达信号

时域和频域中的正负斜率线性调频信号分析。

射频脉冲串分析

如何测量时域和频域中的脉冲序列。