搜索资源列表
MATLAB
- 一个数字带通滤波器,其Ap=1dB,As=34dB,通带从200HZ到400HZ,阻带在100HZ-400HZ,满足上述条件, 设计Chebyshev I型滤波器,Chcbyshev Ⅱ型滤波器和椭圆型滤波器 。-MATLAB
taperline
- 用Matlab编程求解切比雪夫型渐变线的阻抗、线宽和驻波比-Programming with Matlab for solving Chebyshev-type gradient line impedance, line width, and standing-wave ratio
voice_processor
- The purpose of this project is to create a different system for processing voice signals and from which we draw useful conclusions about these brands. More specifically, the system will first filter the voice signal with a pass bandwidth (chebyshe
FastGPS
- GPS卫星坐标的切比雪夫拟合程序,并且实现了快速定位的浮点解的求解。-GPS satellite coordinates Chebyshev fitting procedure, and positioning to achieve a rapid solution of the floating-point solution.
CCGAI
- Turbo C 图形方式下的显示巴特沃斯和切比雪夫滤波器的程序-Turbo C graphics mode display Butterworth and Chebyshev filter procedures
polynomial
- 这是关于切比学夫多项式的资料,介绍了关于插值计算卫星的位置的具体内容。-This is on the Chebyshev polynomial Manabu information about the interpolation calculation of the satellite on the specific content of the location.
bandstop
- 数字带阻滤波器 设计方法和上述的设计方法非常相似,设计的时候注意选择合适的函数,同时将 ftype 改为’stop’,注意函数的参数和返回值。由于方法比较相似,这里只选用一种方法来实现带阻滤波器,暂时选择带阻切比雪夫Ⅱ型滤波器。 带阻滤波器的性能指标为: flp=200 fup=3500 flc=300 fuc=3300 As=46 Ap=3 Fs=22050 -Digital band-stop filter design methods and design of the abo
bss
- IIR数字高通切比雪夫Ⅱ型滤波器幅频与相频曲线 真的很好用 自己完全编写~!-IIR digital high-pass Chebyshev filter type Ⅱ phase frequency and amplitude-frequency curve is really fully prepared with their own good ~!
NumericalAnalysis
- 使用matlab进行数值分析时重要的参考资料,具体包含内容可以看英文描述-This text is written primarily for students/readers who have a good background of high school algebra, geometry, trigonometry, and the fundamentals of differential and integral calculus. This text includes the fol
cheb1_LP_method2
- 低通切比雪夫I型数字滤波器阶数为7阶 在2000Hz通带表现截止在2500Hz阻带边界在过渡带和阻带之间是单调下降波形. -Low-pass Chebyshev Type I digital filter order is 7 in the 2000Hz band pass-band cut-off at 2500Hz stopband performance in the transition zone and the boundary between t
LPQ
- 该源码是一个在MATLAB环境下设计的高通切比雪夫2滤波器。-The source code is a MATLAB environment, to design high-pass Chebyshev filter 2.
CH8
- 8.1 最小二乘曲线拟合hpir1.c 8.2 切比雪夫曲线拟合hchir.c 8.3 最佳一致逼近的里米兹法hremz.c 8.4 矩形域的最小二乘曲面拟合hpir2.c-8.1 Least-squares curve-fitting hpir1.c 8.2 Chebyshev curve fitting the best uniform approximation hchir.c 8.3 years Meeds law hremz.c 8.4 rectangular domain
iirfd11
- IIR滤波器设计的例子,包括切比雪夫和巴特沃斯两种类型。-IIR filter design examples, including Chebyshev, and Butterworth types.
c8_PSDexample
- 这个例子里,我们将独立(白噪声)样本通过有5dB通带纹波的切比雪夫滤波器。 试估计滤波器输出端的PSD。实现这一估计的MATLAB程序如下: -This example, we will be independent (white noise) samples through a 5dB passband ripple Chebyshev filter. Estimate the filter output PSD. MATLAB program to achieve this esti
iir
- 实现有限冲激响应滤波器的设计,按照给定指标采用模拟低通滤波器(巴特沃思低通或者切比雪夫低通)去逼近理想模拟低通滤波器 ,然后通过双线性变换法对模拟滤波器进行数字化,得到数字滤波器 。-To achieve the design of finite impulse response filter, according to a given target analog low-pass filter (Butterworth low-pass or a Chebyshev low-pass) to
LATTICE
- (1)文档中描述了应用窗函数法和切比雪夫逼近法设计FIR滤波器的原理和过程,给出了相应的MATLAB程序。 (2)讨论了线性相位FIR滤波器的LATTICE结构实现方法,并给出了MATLAB程序-(1) document describes the application of window function method and Chebyshev design of FIR filters approximation theory and the process gives the co
IIRwushihui
- 本实验首先按照给定指标采用模拟低通滤波器(巴特沃思低通或者切比雪夫低通)去逼近理想模拟低通滤波器 ,然后通过双线性变换法对模拟滤波器进行数字化,得到数字滤波器 。-In this study, the first indicator in accordance with a given analog low-pass filter (Butterworth low-pass or a Chebyshev low-pass) to approximate the ideal analog low-
IIRcui
- 另一种方法:首先按照给定指标采用模拟低通滤波器(巴特沃思低通或者切比雪夫低通)去逼近理想模拟低通滤波器 ,然后通过双线性变换法对模拟滤波器进行数字化,得到数字滤波器 。-Another way: First, according to a given target analog low-pass filter (Butterworth low-pass or a Chebyshev low-pass) to approximate the ideal analog low-pass filter
GPS
- 均匀线阵方向图形成,包含没有波束指向和30°波束指向,加切比雪夫权值(旁瓣幅度相同)-Uniform linear array pattern formation, with no beam pointing and 30 ° beam pointing, Gache Chebyshev weights (the same side-lobe amplitude)
filter
- 可计算生成巴特沃斯、切比雪夫原型滤波器,转换为数字滤波器,并可直接进行滤波-Computable generating Butterworth, Chebyshev prototype filter, is converted to digital filters, can be directly filtered