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Seppl
2024-07-18 22:04:22 +02:00
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const.py Normal file
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from functools import cache
import numpy as np
import const_utils
# https://www.ieee802.org/3/bn/public/nov13/prodan_3bn_02_1113.pdf
@cache
def gray_1d(k, label):
const_utils.gray_1d_input_validation(k, label)
# special case
if k == 1:
return 1 if label==0 else -1
# all other cases -> recurse
b0, new_symbol = const_utils.next_symbol(k, label)
return (1-2*b0)*(2**(k-1)+gray_1d(k-1, new_symbol))
def gray_2d(n, m, label):
const_utils.gray_2d_input_validation(n, m, label)
# n or m is 0
if (coord:=const_utils.gray_2d_handle_1d(n, m, label)) is not None:
return coord
# all other cases
symbol_i, symbol_q = const_utils.split_symbol(n, m, label)
return (gray_1d(n, symbol_i), gray_1d(m, symbol_q))
def hamming_dist(a, b):
if not isinstance(a, int):
raise ValueError('a must be an integer')
if not isinstance(b, int):
raise ValueError('b must be an integer')
def euclidean_distance(coord1, coord2):
if isinstance(coord1, int):
return abs(coord1 - coord2)
return np.sqrt((coord1[0] - coord2[0])**2 + (coord1[1] - coord2[1])**2)
def find_nearest(coord, coords):
min_distance = float('inf')
nearest_symbols = []
for c in coords:
dist = euclidean_distance(coord, c)
if dist == 0:
continue
elif dist < min_distance:
min_distance = dist
nearest_symbols = [c]
elif dist == min_distance:
nearest_symbols.append(c)
# else:
# pass
return nearest_symbols
def gray_penalty(constellation):
# constellation: {label_0:coordinate_0, label_1:coordinate_1, .., label_2^n-1:coordinate_2^n-1}
# 2^n-QAM -> 2^n symbols S_i, where i=0,1,..2^n-1, ex. S_0 = (-3,-3) or S_0 = -2
# N(S_i): set of (euclidean) nearest symbols S_j -> N((-3,-3)) = {(-3,-2), (-3,-4), (-2,-3), (-4,-3)}
# |N(S_i)|: size of set N(S_i)
# l(S): label given by mapping -> inverse of gray_Qd -> generate all symbols/labels for given constellation
# wt(l_1, l_2), hamming distance btw. two labels
t = len(constellation)
inverted_constellation = {tuple(symbol):label for label,symbol in constellation.items() if label != 'meta'} # -> invert constellation dict
syms = [symbol for _, symbol in constellation.items()]
if (n:=np.log2(t)) != int(n):
raise ValueError('only constellations with 2^n points supported')
G = 0
for li, si in constellation.items():
N = find_nearest(si, syms)
size_N = len(N)
wt = sum(hamming_dist(inverted_constellation[tuple(sj)], li) for sj in N)
G += wt/size_N
G /= t
return G
def find_rows_columns(coordinates):
if not coordinates:
return 0, 0
min_row = min(coord[0] for coord in coordinates.values())
max_row = max(coord[0] for coord in coordinates.values())
row_spacing = abs(coordinates[next(iter(coordinates))][0] - coordinates[next(iter(coordinates))][0])
min_col = min(coord[1] for coord in coordinates.values())
max_col = max(coord[1] for coord in coordinates.values())
col_spacing = abs(coordinates[next(iter(coordinates))][1] - coordinates[next(iter(coordinates))][1])
num_rows = (max_row - min_row) // row_spacing + 1
num_cols = (max_col - min_col) // col_spacing + 1
return num_rows, num_cols
def transform_rectangular_mapping(constellation):
n, m = find_rows_columns(constellation)
# example: 32-qam -> 2^(2n+1) -> n = 2
two_n1 = np.log2(len(constellation))
if int(two_n1) != two_n1:
raise ValueError('only constellations with 2^m points allowed')
if n == 1 or m == 1: # 1D-constellation
return constellation
n = c/2
m = r/2
const_utils._validate_integer(n, 'n')
const_utils._validate_integer(m, 'm')
if n == m: # square 2^(2n)-QAM
return constellation
if n == 2 and m == 1: # rectangular 8-QAM (4*2)
return transform_8QAM(constellation)
elif n == m+2:
new_const = {}
s = 2**(n-1)
for label, symbol in constellation.items():
def transform_8QAM(constellation):
new_const = {}
for label, symbol in constellation.items():
if symbol[0] < 3:
new_const[label] = symbol
else:
i_rct, q_rct = symbol
i_cr = -np.sign(i_rct)*(4-np.abs(i_rct))
q_cr = np.sign(q_rct)*(np.abs(q_rct)+2)
new_const[label] = [i_cr, q_cr]
return new_const# rectangular 2^(m+n)-QAM
if __name__ == '__main__':
# print(gray_1d(2, 0))
print(gray_2d(2, 3, 4))
print(gray_2d(0, 2, 4))

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import pytest
from const import gray_1d
# Happy path tests with various realistic test values
@pytest.mark.parametrize("k, symbol, expected", [
(0, 0, 0), # k=0 case
(1, 0, 1), # k=1, symbol=0 case
(1, 1, -1), # k=1, symbol=1 case
(2, 0, 3), # k=2, symbol=0 case
(2, 1, 1), # k=2, symbol=1 case
(2, 2, -3), # k=2, symbol=2 case
(2, 3, -1), # k=2, symbol=3 case
], ids=[
"k=0_symbol=0",
"k=1_symbol=0",
"k=1_symbol=1",
"k=2_symbol=0",
"k=2_symbol=1",
"k=2_symbol=2",
"k=2_symbol=3"
])
def test_gray_1d_happy_path(k, symbol, expected):
# Act
result = gray_1d(k, symbol)
# Assert
assert result == expected
# Various edge cases
@pytest.mark.parametrize("k, symbol, expected", [
(3, 0, 7), # k=3, symbol=0 case
(3, 7, -3), # k=3, symbol=7 case
(4, 0, 15), # k=4, symbol=0 case
(4, 15, -5), # k=4, symbol=15 case
], ids=[
"k=3_symbol=0",
"k=3_symbol=7",
"k=4_symbol=0",
"k=4_symbol=15"
])
def test_gray_1d_edge_cases(k, symbol, expected):
# Act
result = gray_1d(k, symbol)
# Assert
assert result == expected
# Various error cases
@pytest.mark.parametrize("k, symbol, exception", [
(-1, 0, ValueError), # k is negative
(1, -1, ValueError), # symbol is negative
(1, 2, ValueError), # symbol is out of range for k=1
(2, 4, ValueError), # symbol is out of range for k=2
], ids=[
"k_negative",
"symbol_negative",
"symbol_out_of_range_k1",
"symbol_out_of_range_k2"
])
def test_gray_1d_error_cases(k, symbol, exception):
# Act and Assert
with pytest.raises(exception):
gray_1d(k, symbol)

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from const import gray_1d
def _validate_integer(value, name):
if not isinstance(value, int):
raise ValueError(f'{name} must be an integer')
def _validate_range(value, name, min_val=None, max_val=None):
if max_val is not None and value > max_val:
raise ValueError(f'{name} must be \u2265 {max_val}')
if min_val is not None and value < min_val:
raise ValueError(f'{name} must be \u2264 {min_val}')
def gray_1d_input_validation(k, symbol):
_validate_integer(symbol, 'symbol')
_validate_integer(k, 'k')
_validate_range(k, 'k', min_val=1)
_validate_range(symbol, 'symbol', min_val=0, max_val=2**k-1)
def next_symbol(k, symbol):
bits = format(symbol, 'b').zfill(k)
b0 = int(bits[0])
new_symbol = int(bits[1:], 2)
return b0,new_symbol
def gray_2d_input_validation(n, m, symbol):
_validate_integer(n, 'n')
_validate_integer(m, 'm')
_validate_integer(symbol, 'symbol')
_validate_range(n, 'n', min_val=0)
min_m = 0 if n > 0 else 1
_validate_range(m, 'm', min_val=min_m)
_validate_range(symbol, 'symbol', min_val=0, max_val=2**(m+n)-1)
def gray_2d_handle_1d(n, m, symbol):
n,m,swapped = m,n,True if n == 0 else n,m,False # swap n and m if n is zero -> if only one > 0, it's n
if m == 0:
return (gray_1d(n, symbol),None) if swapped else (None,gray_1d(n, symbol))
else:
return None
def split_symbol(n, m, symbol):
bits = format(symbol, 'b').zfill(n+m)
symbol_i = int(bits[:n], 2)
symbol_q = int(bits[n:], 2)
return symbol_i,symbol_q