#!/usr/bin/env python
##################################################
# Gnuradio Python Flow Graph
# Title: IQ Imbalance Generator
# Author: mettus
# Generated: Thu Aug 1 12:08:07 2013
##################################################
from gnuradio import blocks
from gnuradio import gr
from gnuradio.filter import firdes
import math
class iqbal_gen(gr.hier_block2):
def __init__(self, magnitude=0, phase=0, mode=0):
'''
This block implements the single branch IQ imbalance
transmitter and receiver models.
Developed from source (2014):
"In-Phase and Quadrature Imbalance:
Modeling, Estimation, and Compensation"
TX Impairment:
{R}--|Multiply: 10**(mag/20)|--+--|Multiply: cos(pi*degree/180)|--X1
Input ---|Complex2Float|---| +--|Multiply: sin(pi*degree/180)|--X2
{I}--| Adder |
X2--| (+) |--X3
X1--{R}--| Float 2 |--- Output
X3--{I}--| Complex |
RX Impairment:
{R}--|Multiply: cos(pi*degree/180)|-------| |
Input ---|Complex2Float|---| | Adder |--X1
{I}--+--|Multiply: sin(pi*degree/180)|----| (+) |
|
+--X2
X1--|Multiply: 10**(mag/20)|--{R}--| Float 2 |--- Output
X2---------------------------{I}--| Complex |
(ASCII ART monospace viewing)
'''
gr.hier_block2.__init__(
self, "IQ Imbalance Generator",
gr.io_signature(1, 1, gr.sizeof_gr_complex*1),
gr.io_signature(1, 1, gr.sizeof_gr_complex*1),
)
##################################################
# Parameters
##################################################
self.magnitude = magnitude
self.phase = phase
self.mode = mode
##################################################
# Blocks
##################################################
# Same blocks for Transmitter and Receiver
self.mag = blocks.multiply_const_vff((math.pow(10,magnitude/20.0), ))
self.sin_phase = blocks.multiply_const_vff((math.sin(phase*math.pi/180.0), ))
self.cos_phase = blocks.multiply_const_vff((math.cos(phase*math.pi/180.0), ))
self.f2c = blocks.float_to_complex(1)
self.c2f = blocks.complex_to_float(1)
self.adder = blocks.add_vff(1)
##################################################
# Connections
##################################################
if(self.mode):
# Receiver Mode
self.connect((self, 0), (self.c2f, 0))
self.connect((self.c2f, 0), (self.cos_phase, 0))
self.connect((self.cos_phase, 0), (self.adder, 0))
self.connect((self.c2f, 1), (self.sin_phase, 0))
self.connect((self.sin_phase, 0), (self.adder, 1))
self.connect((self.adder, 0), (self.mag, 0))
self.connect((self.mag, 0), (self.f2c, 0))
self.connect((self.c2f, 1), (self.f2c, 1))
self.connect((self.f2c, 0), (self, 0))
else:
# Transmitter Mode
self.connect((self, 0), (self.c2f, 0))
self.connect((self.c2f, 0), (self.mag, 0))
self.connect((self.mag, 0), (self.cos_phase, 0))
self.connect((self.cos_phase, 0), (self.f2c, 0))
self.connect((self.mag, 0), (self.sin_phase, 0))
self.connect((self.sin_phase, 0), (self.adder, 0))
self.connect((self.c2f, 1), (self.adder, 1))
self.connect((self.adder, 0), (self.f2c, 1))
self.connect((self.f2c, 0), (self, 0))
# QT sink close method reimplementation
def get_magnitude(self):
return self.magnitude
def set_magnitude(self, magnitude):
self.magnitude = magnitude
self.mag.set_k((math.pow(10,self.magnitude / 20.0), ))
def get_phase(self):
return self.phase
def set_phase(self, phase):
self.phase = phase
self.sin_phase.set_k((math.sin(self.phase*math.pi/180.0), ))
self.cos_phase.set_k((math.cos(self.phase*math.pi/180.0), ))