# -*- coding: utf-8 -*-
# This code is part of Qiskit.
#
# (C) Copyright IBM 2017, 2021.
#
# This code is licensed under the Apache License, Version 2.0. You may
# obtain a copy of this license in the LICENSE.txt file in the root directory
# of this source tree or at http://www.apache.org/licenses/LICENSE-2.0.
#
# Any modifications or derivative works of this code must retain this
# copyright notice, and modified files need to carry a notice indicating
# that they have been altered from the originals.
from qiskit_metal import draw, Dict
from qiskit_metal.qlibrary.core import QComponent
import numpy as np
[docs]
class CoupledLineTee(QComponent):
"""Generates a three pin (+) structure comprised of a primary two pin CPW
transmission line, and a secondary one pin neighboring CPW transmission
line that is capacitively/inductively coupled to the primary. Such a
structure can be used, as an example, for generating CPW resonator hangars
off of a transmission line.
Inherits QComponent class.
::
+----------------------------+
------------------------------
|
|
|
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+
.. image::
CoupledLineTee.png
.. meta::
Coupled Line Tee
Default Options:
* prime_width: '10um' -- The width of the trace of the two pin CPW transmission line
* prime_gap: '6um' -- The dielectric gap of the two pin CPW transmission line
* second_width: '10um' -- The width of the trace of the one pin CPW transmission line
* second_gap: '6um' -- The dielectric gap of the one pin CPW transmission line
* coupling_space: '3um' -- The amount of ground plane between the two transmission lines
* coupling_length: '100um' -- The length of parallel between the two transmission lines
note: this includes the distance of the curved second of the second line
* down_length: '100um' -- The length of the hanging part of the resonator, including the curved region
* fillet: '25um'
* mirror: False -- Flips the hanger around the y-axis
* open_termination: True -- sets if the termination of the second line at the coupling side
is an open to ground or short to ground
"""
component_metadata = Dict(short_name='cpw', _qgeometry_table_path='True')
"""Component metadata"""
#Currently setting the primary CPW length based on the coupling_length
#May want it to be it's own value that the user can control?
default_options = Dict(prime_width='10um',
prime_gap='6um',
second_width='10um',
second_gap='6um',
coupling_space='3um',
coupling_length='100um',
down_length='100um',
fillet='25um',
mirror=False,
open_termination=True)
"""Default connector options"""
TOOLTIP = """Generates a three pin (+)
structure comprised of a primary two
pin CPW transmission line, and a
secondary one pin neighboring CPW
transmission line that is
capacitively/inductively coupled
to the primary."""
[docs]
def make(self):
"""Build the component."""
p = self.p
prime_cpw_length = p.coupling_length * 2
second_flip = 1
if p.mirror:
second_flip = -1
#Primary CPW
prime_cpw = draw.LineString([[-prime_cpw_length / 2, 0],
[prime_cpw_length / 2, 0]])
#Secondary CPW
second_down_length = p.down_length
second_y = -p.prime_width / 2 - p.prime_gap - p.coupling_space - p.second_gap - p.second_width / 2
second_cpw = draw.LineString(
[[second_flip * (-p.coupling_length / 2), second_y],
[second_flip * (p.coupling_length / 2), second_y],
[
second_flip * (p.coupling_length / 2),
second_y - second_down_length
]])
second_termination = 0
if p.open_termination:
second_termination = p.second_gap
second_cpw_etch = draw.LineString(
[[
second_flip * (-p.coupling_length / 2 - second_termination),
second_y
], [second_flip * (p.coupling_length / 2), second_y],
[
second_flip * (p.coupling_length / 2),
second_y - second_down_length
]])
#Rotate and Translate
c_items = [prime_cpw, second_cpw, second_cpw_etch]
c_items = draw.rotate(c_items, p.orientation, origin=(0, 0))
c_items = draw.translate(c_items, p.pos_x, p.pos_y)
[prime_cpw, second_cpw, second_cpw_etch] = c_items
#Add to qgeometry tables
self.add_qgeometry('path', {'prime_cpw': prime_cpw},
width=p.prime_width)
self.add_qgeometry('path', {'prime_cpw_sub': prime_cpw},
width=p.prime_width + 2 * p.prime_gap,
subtract=True)
self.add_qgeometry('path', {'second_cpw': second_cpw},
width=p.second_width,
fillet=p.fillet)
self.add_qgeometry('path', {'second_cpw_sub': second_cpw_etch},
width=p.second_width + 2 * p.second_gap,
subtract=True,
fillet=p.fillet)
#Add pins
prime_pin_list = prime_cpw.coords
second_pin_list = second_cpw.coords
self.add_pin('prime_start',
points=np.array(prime_pin_list[::-1]),
width=p.prime_width,
input_as_norm=True)
self.add_pin('prime_end',
points=np.array(prime_pin_list),
width=p.prime_width,
input_as_norm=True)
self.add_pin('second_end',
points=np.array(second_pin_list[1:]),
width=p.second_width,
input_as_norm=True)