RU2014106853A

RU2014106853A - METHOD FOR FORMING SIGNALS OF SQUARE AMPLITUDE MANIPULATION

Info

Publication number: RU2014106853A
Application number: RU2014106853/07A
Authority: RU
Inventors: Александр Леонидович Кашин; Рубен Александрович Маркосян; Андрей Леонидович Костырев; Адам Адамович Римашевский; Сергей Викторович Дворников; Юрий Иванович Григорьев
Original assignee: Закрытое акционерное общество ЗАО "ПРОЕКТНО-КОНСТРУКТОРСКОЕ БЮРО "РИО"
Priority date: 2014-02-24
Filing date: 2014-02-24
Publication date: 2015-08-27
Also published as: RU2562257C1

Abstract

1. Способ формирования сигналов квадратурной амплитудной манипуляции, заключающийся в том, что генерируют синусоидальный сигнал, из которого формируют исходные значения напряжения квадратурнойи синфазнойсоставляющих, которые манипулируют в зависимости от значений первого r, второго r, третьего rи четвертого rинформационных битов, причем фазы изменяют на 180° для, если r=1, а дляесли r=1, после чего манипулированные синфазную и квадратурную составляющие суммируют, отличающийся тем, что все поступающие информационные биты разделяют на блоки по четыре бита, причем квадратурную и синфазную составляющие манипулируют следующим образом, если r=0, r=1, r=1 и r=0, тоумножают на 18/16,умножают на 14/16; если r=0, r=1, r=0 и r=0, тоумножают на 14/16,умножают на 6/16; если r=0, r=1, r=1 и r=1, тоумножают на 10/16,умножают на 18/16; если r=0, r=1, r=0 и r=1, тоумножают на 6/16,умножают на 10/16; если r=0, r=0, r=1 и r=0, тоумножают на 17/16,умножают на 7/16; если r=0, r,=0, r=0 и r=0, тоумножают на 15/16,умножают на 17/16; если r=0, r=0, r=1 и r=1, тоумножают на 9/16,умножают на 7/16; если r=0, r=0, r=0 и r=1, тоумножают на 7/16,умножают на 15/16; если r=1, r=0, r=1 и r=0, тоумножают на 6/16,умножают на 10/16; если r=1, r=0, r=0 и r=0, тоумножают на 10/16,умножают на 18/16; если r=1, r=0, r=1 и r=1, тоумножают на 14/16,умножают на 6/16; если r=1, r=0, r=0 и r=1, тоумножают на 18/16,умножают на 14/16; если r=1, r=1, r=1 и r=0, тоумножают на 7/16,умножают на 15/16; если r=1, r=1, r=0 и r=0 тоумножают на 9/16,умножают на 7/16; если r=1, r=1, r=1 и r=1, тоумножают на 15/16,умножают на 17/16; если r=1, r=1, r=0 и r=1, тоумножают на 17/16,умножают на 9/16.2. Способ по п.1, отличающийся тем, что суммируют манипулированные значения синфазнойи квадратурнойсоставляющих по формуле.1. The method of generating signals of quadrature amplitude manipulation, which consists in generating a sinusoidal signal, from which form the initial voltage values of the quadrature and in-phase components, which manipulate depending on the values of the first r, second r, third r and fourth information bits, and the phases are changed to 180 ° for, if r = 1, and for if r = 1, after which the manipulated in-phase and quadrature components are added up, characterized in that all incoming information bits are divided into blocks n four bits, wherein the in-phase and quadrature components are manipulated as follows when r = 0, r = 1, r = 1 and r = 0, toumnozhayut 18/16 is multiplied by 14/16; if r = 0, r = 1, r = 0 and r = 0, then multiply by 14/16, multiply by 6/16; if r = 0, r = 1, r = 1 and r = 1, then multiply by 10/16, multiply by 18/16; if r = 0, r = 1, r = 0 and r = 1, then multiply by 6/16, multiply by 10/16; if r = 0, r = 0, r = 1 and r = 0, then multiply by 17/16, multiply by 7/16; if r = 0, r, = 0, r = 0 and r = 0, then multiply by 15/16, multiply by 17/16; if r = 0, r = 0, r = 1 and r = 1, then multiply by 9/16, multiply by 7/16; if r = 0, r = 0, r = 0 and r = 1, then multiply by 7/16, multiply by 15/16; if r = 1, r = 0, r = 1 and r = 0, then multiply by 6/16, multiply by 10/16; if r = 1, r = 0, r = 0 and r = 0, then multiply by 10/16, multiply by 18/16; if r = 1, r = 0, r = 1 and r = 1, then multiply by 14/16, multiply by 6/16; if r = 1, r = 0, r = 0 and r = 1, then multiply by 18/16, multiply by 14/16; if r = 1, r = 1, r = 1 and r = 0, then multiply by 7/16, multiply by 15/16; if r = 1, r = 1, r = 0 and r = 0 then multiply by 9/16, multiply by 7/16; if r = 1, r = 1, r = 1 and r = 1, then multiply by 15/16, multiply by 17/16; if r = 1, r = 1, r = 0 and r = 1, then multiply by 17/16, multiply by 9 / 16.2. The method according to claim 1, characterized in that the manipulated values of the in-phase and quadrature components according to the formula are summed.

Claims

1. The method of generating signals of quadrature amplitude manipulation, which consists in generating a sinusoidal signal, from which form the initial values of the voltage quadrature

{\vec{u}}_{and from x}^{Q}

and common mode

{\vec{u}}_{and from x}^{I}

components that manipulate depending on the values of the first r ₁ , second r ₂ , third r ₃ and fourth r ₄ information bits, and the phases are changed by 180 ° for

{\vec{u}}_{and from x}^{I}

if r ₂ = 1, and for

{\vec{u}}_{and from x}^{Q}

if r ₁ = 1, after which the manipulated in-phase and quadrature components are summed, characterized in that all incoming information bits are divided into blocks of four bits, and the quadrature and in-phase components are manipulated as follows, if r ₁ = 0, r ₂ = 1, r ₃ = 1 and r ₄ = 0, then

{\vec{u}}_{and from x}^{Q}

multiply by 18/16,

{\vec{u}}_{and from x}^{I}

multiply by 14/16; if r ₁ = 0, r ₂ = 1, r ₃ = 0 and r ₄ = 0, then

{\vec{u}}_{and from x}^{Q}

multiply by 14/16,

{\vec{u}}_{and from x}^{I}

multiply by 6/16; if r ₁ = 0, r ₂ = 1, r ₃ = 1 and r ₄ = 1, then

{\vec{u}}_{and from x}^{Q}

multiply by 10/16,

{\vec{u}}_{and from x}^{I}

multiply by 18/16; if r ₁ = 0, r ₂ = 1, r ₃ = 0 and r ₄ = 1, then

{\vec{u}}_{and from x}^{Q}

multiply by 6/16,

{\vec{u}}_{and from x}^{I}

multiplied by 10/16; if r ₁ = 0, r ₂ = 0, r ₃ = 1 and r ₄ = 0, then

{\vec{u}}_{and from x}^{Q}

multiply by 17/16,

{\vec{u}}_{and from x}^{I}

multiply by 7/16; if r ₁ = 0, r ₂ , = 0, r ₃ = 0 and r ₄ = 0, then

{\vec{u}}_{and from x}^{Q}

multiply by 15/16,

{\vec{u}}_{and from x}^{I}

multiply by 17/16; if r ₁ = 0, r ₂ = 0, r ₃ = 1 and r ₄ = 1, then

{\vec{u}}_{and from x}^{Q}

multiply by 9/16,

{\vec{u}}_{and from x}^{I}

multiply by 7/16; if r ₁ = 0, r ₂ = 0, r ₃ = 0 and r ₄ = 1, then

{\vec{u}}_{and from x}^{Q}

multiply by 7/16,

{\vec{u}}_{and from x}^{I}

multiply by 15/16; if r ₁ = 1, r ₂ = 0, r ₃ = 1 and r ₄ = 0, then

{\vec{u}}_{and from x}^{Q}

multiply by 6/16,

{\vec{u}}_{and from x}^{I}

multiplied by 10/16; if r ₁ = 1, r ₂ = 0, r ₃ = 0 and r ₄ = 0, then

{\vec{u}}_{and from x}^{Q}

multiply by 10/16,

{\vec{u}}_{and from x}^{I}

multiply by 18/16; if r ₁ = 1, r ₂ = 0, r ₃ = 1 and r ₄ = 1, then

{\vec{u}}_{and from x}^{Q}

multiply by 14/16,

{\vec{u}}_{and from x}^{I}

multiply by 6/16; if r ₁ = 1, r ₂ = 0, r ₃ = 0 and r ₄ = 1, then

{\vec{u}}_{and from x}^{Q}

multiply by 18/16,

{\vec{u}}_{and from x}^{I}

multiply by 14/16; if r ₁ = 1, r ₂ = 1, r ₃ = 1 and r ₄ = 0, then

{\vec{u}}_{and from x}^{Q}

multiply by 7/16,

{\vec{u}}_{and from x}^{I}

multiply by 15/16; if r ₁ = 1, r ₂ = 1, r ₃ = 0 and r ₄ = 0 then

{\vec{u}}_{and from x}^{Q}

multiply by 9/16,

{\vec{u}}_{and from x}^{I}

multiply by 7/16; if r ₁ = 1, r ₂ = 1, r ₃ = 1 and r ₄ = 1, then

{\vec{u}}_{and from x}^{Q}

multiply by 15/16,

{\vec{u}}_{and from x}^{I}

multiply by 17/16; if r ₁ = 1, r ₂ = 1, r ₃ = 0 and r ₄ = 1, then

{\vec{u}}_{and from x}^{Q}

multiply by 17/16,

{\vec{u}}_{and from x}^{I}

multiply by 9/16.

2. The method according to claim 1, characterized in that the manipulated common-mode values are summed

{\vec{u}}_{M}^{I}

and quadrature

{\vec{u}}_{M}^{Q}

components according to the formula

\sqrt{{({\vec{u}}_{M}^{Q})}^{2} + {({\vec{u}}_{M}^{I})}^{2}}

.