VM600-XMV16 振动状态监控模块

VM600-XMV16 振动状态监控模块

VM600的高质量、高可靠性状态监控模块Mk2/VM600机架式机械监控系统–针对高性能振动监控应用进行了优化。XMV16振动状态监控模块提供16个动态通道和4个转速计(速度)通道，所有通道均可独立配置。XMV16处理模块始终与相关的XIO16T输入/输出模块一起作为一组模块(卡对)使用。

特征
16个动态通道和4个转速通道
每个动态通道和每个双通道zui多20个处理输出(每个xmv 16 12个)
利用异步(固定频率)或同步(顺序跟踪)采样在所有通道上同时采集数据
24位数据采集，高信噪比数据处理，高分辨率FFT高达每500 ms 6400行
专为与VibroSight软件配合使用而设计
具有更大字长的CPU需要更多的电路，因此物理上更大，成本更高，消耗更多的功率(因此产生更多的热量)。因此，更小的4位或8位微控制器即使有更大字长(如16位、32位、64位甚至128位)的CPU可用，也普遍用于现代应用中。然而，当需要更高的性能时，更大的字长(更大的数据范围和地址空间)可能会利大于弊。CPU可以具有比字长更短的内部数据路径，以减小尺寸和成本。例如，即使IBM系统/360 指令组是一个32位指令集，System/360型号30和型号40在算术逻辑单元中有8位数据路径，因此32位加法运算需要四个周期，每8位操作数一个周期，即使摩托罗拉68000系列指令集是一个32位指令集摩托罗拉68000和摩托罗拉68010在算术逻辑单元中有16位数据路径，因此32位加法需要两个周期。

为了获得较低和较高位长提供的一些优点，许多指令集对于整数和浮点数据具有不同位宽，允许实现指令集的CPU对于设备的不同部分具有不同的位宽。例如，IBM系统/360指令集主要是32位，但支持64位浮点值，以提高浮点数的准确性和范围。[30]System/360 Model 65有一个用于十进制和定点二进制运算的8位加法器和一个用于浮点运算的60位加法器。[69]许多后来的CPU设计使用类似的混合位宽，特别是当处理器是用于通用用途，需要整数和浮点功能的合理平衡时。

VM600-XMV16 振动状态监控模块

VM600's high quality, high reliability condition monitoring module Mk2/VM600 Rack Mounted Mechanical Monitoring System - optimized for high-performance vibration monitoring applications. The XMV16 vibration condition monitoring module offers 16 dynamic channels and 4 tachometer (speed) channels, all of which can be configured independently. The XMV16 processing module is always used as a set of modules (card pairs) together with the associated XIO16T input/output modules.

trait
16 dynamic channels and 4 RPM channels
Up to 20 processing outputs per dynamic channel and per dual channel (16 12 per xmv)
Capture data simultaneously on all channels using asynchronous (fixed frequency) or synchronous (sequential tracking) sampling
24-bit data acquisition, high signal-to-noise ratio data processing, high-resolution FFT up to 6400 lines per 500 ms
Designed to work with VibroSight software
Cpus with larger word lengths require more circuitry, are therefore physically larger, cost more, and consume more power (and therefore generate more heat). Therefore, smaller 4 - or 8-bit microcontrollers are commonly used in modern applications even when cpus with larger word lengths (such as 16 -, 32 -, 64 -, or even 128-bit) are available. However, when higher performance is required, a larger word length (larger data range and address space) may do more good than harm. Cpus can have internal data paths that are shorter than word length to reduce size and cost. For example, even though the IBM System/360 instruction set is a 32-bit instruction set, the System/360 model 30 and model 40 have 8-bit data paths in the arithmetic logic unit, so the 32-bit addition operation requires four cycles, one for each 8-bit operand. Even though the MOTOROLA 68000 series instruction set is a 32-bit instruction set, the MOTOROLA 68000 and MOTOROLA 68010 have 16-bit data paths in the arithmetic logic unit, so 32-bit addition takes two cycles.

To get some of the advantages offered by lower and higher length, many instruction sets have different bit widths for integer and floating point data, allowing the CPU implementing the instruction set to have different bit widths for different parts of the device. For example, the IBM system /360 instruction set is primarily 32-bit but supports 64-bit floating-point values to improve the accuracy and range of floating-point numbers. [30] The System/360 Model 65 had an 8-bit adder for decimal and fixed-point binary operations and a 60-bit adder for floating-point operations. [69] Many later CPU designs used similar hybrid bit widths, especially when the processor was intended for general purpose and required a reasonable balance of integer and floating-point functionality.

VM600-XMV16 振动状态监控模块