linear+approximation

кусочно-линейная аппроксимация

piecewise-linear approximation

кусочно-линейная аппроксимация

piecewise-linear approximation

При линейной аппроксимации по $х$

In the linear approximation in $x$

прямая аппроксимации

( кривой) linear approximation

линейная симплексная аппроксимация

linear simplex approximation

линейное уравнение

linear equation

уравнение, содержащее посторонние корни — redundant equation

уравнение состояния Клайперона — Clapeyron equation of state

уравнение первого приближения — first approximation equation

уравнение для установившегося режима — steady-state equation

уравнение, содержащее определитель — determinantal equation

преобразование

conversion, converting, alteration, inversion связь, ( данных из одной формы в другую) map вчт., mapping, transduction, transform, transformation, translation, transposition

* * *

преобразова́ние с.
conversion, transformation; мат. manipulation, transformation

путё́м несло́жных преобразова́ний получа́ем … — a little manipulation yields …

алгебраи́ческое преобразова́ние — algebraic transformation, algebraic manipulation

преобразова́ние ана́лог — код — analog-to-digital [A/ D] conversion

преобразова́ние ана́лог — код, вре́мя-и́мпульсное — analog-to-digital [A/ D] time conversion

преобразова́ние ана́лог — код кодои́мпульсным ме́тодом — analog-to-digital [A/ D] conversion by a comparison [pulse-code] method

преобразова́ние ана́лог — код ме́тодом простра́нственного коди́рования — analog-to-digital [A/ D] conversion by a code(d)-pattern method

преобразова́ние ана́лог — код с поразря́дным уравнове́шиванием — successive-approximation analog-to-digital [A/ D] conversion, A/ D conversion by the successive approximation method

преобразова́ние ана́лог — код спо́собом взве́шивания — analog-to-digital [A/ D] conversion by the successive approximation method [by feedback subtraction]

преобразова́ние ана́лог — код, часто́тно-и́мпульсное — analog-to-digital [A/ D] frequency conversion

ана́лого-цифрово́е преобразова́ние одни́м отсчё́том — total-value analog-to-digital [A/ D] conversion

ана́лого-цифрово́е преобразова́ние после́довательным отсчё́том — incremental analog-to-digital [A/ D] conversion

ана́лого-цифрово́е преобразова́ние сравне́нием и вычита́нием — analog-to-digital [A/ D] conversion by continuous comparison

ана́лого-цифрово́е преобразова́ние сравне́нием и вычита́нием с обра́тной свя́зью — successive-approximation comparison analog-to-digital [A/ D] conversion

бу́лево преобразова́ние — Boolean transformation

взаи́мно однозна́чное преобразова́ние — one-to-one transformation

преобразова́ния Галиле́я — Galilean transformation

преобразова́ние да́нных

1. data conversion

2. ( предварительное) data reduction

преобразова́ние дискре́тных да́нных в непреры́вные — digital-to-analog conversion

преобразова́ние звезды́ в треуго́льник эл. — star-(to-)delta conversion, star-(to-)delta transformation

преобразова́ние ко́да — code conversion

конфо́рмное преобразова́ние — conformal transformation

преобразова́ние Лапла́са — Laplace transform

проводи́ть преобразова́ние по Лапла́су — apply the Laplace transformation, take the Laplace transform

лине́йное преобразова́ние — linear transformation

логи́ческое преобразова́ние в це́лях минимиза́ции свя́зей алгори́тма — minimization by Boolean functions

преобразова́ния Ло́ренца ( пространственных и временных координат) — Lorentz's transformations

преобразова́ние многоуго́льник — звезда́ эл. — mesh-star conversion

преобразова́ние прое́кции картогр. — rectification of projection

преобразова́ние свё́ртки мат. — convolution transform

преобразова́ние сигна́ла одного́ ви́да эне́ргии в друго́й — (signal) transduction

преобразова́ние сигна́ла одного́ ви́да эне́ргии в друго́й, оптикоэлектро́нное — optic-to-electronic (signal) transduction

преобразова́ние п [m2]-обра́зной цепи́ в П[m2]-обра́зную — tee-to-pi [T-to- ] transformation

преобразова́ние треуго́льника в звезду́ эл. — delta-(to-)star conversion, delta-(to-)star transformation

функциона́льное преобразова́ние вчт. — function generation

преобразова́ние Фурье́ — Fourier transform

преобразова́ние Фурье́, бы́строе [БПФ] — fast Fourier transform, FFT

ци́фро-ана́логовое преобразова́ние — digital-to-analog conversion

преобразова́ние частоты́

1. радио frequency conversion

2. ( в многоканальной связи) frequency translation

преобразова́ние частоты́, группово́е ( в многоканальной связи) — group (frequency) translation

осуществля́ть группово́е преобразова́ние частоты́ на несу́щей частоте́ — translate the carrier

преобразова́ние частоты́, двухсе́точное радио — double-grid injection frequency conversion

преобразова́ние частоты́, индивидуа́льное ( в многоканальной связи) — channel translation

преобразова́ние эне́ргии, прямо́е — direct energy conversion

преобразова́ние эне́ргии, термоэлектри́ческое — thermoelectric energy conversion

преобразова́ние эне́ргии, термоэмиссио́нное — thermionic energy conversion

преобразова́ние эне́ргии, электромехани́ческое — electromechanical energy conversion

линейная симплексная аппроксимация

Makarov: linear simplex approximation

Определенные артикли перед существительными, которые снабжены ссылками

The differential problem (1) can be reduced to the form (2)

The asymptotic formula (1) follows from the above lemma

The differential equation (1) can be solved numerically

What is needed in the final result is a simple bound on quantities of the form (1)

The inequality (1) (артикль можно опустить) shows that $a>b$

The bound (estimate) (2) is not quite as good as the bound (estimate) (1)

If the norm of $A$ satisfies the restriction (1), then by the estimate (2) this term is less than unity

Since the spectral radius of $A$ belongs to the region (1), this iterative method converges for any initial guesses

The array (1) is called the matrix representing the linear transformation of $f$

It should be noted that the approximate inequality (1) bounds only the absolute error in $x$

The inequality (1) shows that...

The second step in our analysis is to substitute the forms (1) and (2) into this equation and simplify it by dropping higher-order terms

For small $ze$ the approximation (1) is very good indeed

A matrix of the form (1), in which some eigenvalue appears in more than one block, is called a derogatory matrix

The relation between limits and norms is suggested by the equivalence (1)

For this reason the matrix norm (1) is seldom encountered in the literature

To establish the inequality (1) from the definition (2)

Our conclusion agrees with the estimate (1)

The characterization is established in almost the same way as the results of Theorem 1, except that the relations (1) and (2) take place in the eigenvalue-eigenvector relation...

This vector satisfies the differential equation (1)

The Euclidean vector norm (2) satisfies the properties (1)

The bound (1) ensures only that these elements are small compared with the largest element of $A$

There is some terminology associated with the system (1) and the matrix equation (2)

A unique solution expressible in the form (1) restricts the dimensions of $A$

The factorization (1) is called the $LU$-factorization

It is very uncommon for the condition (1) to be violated

The relation (1) guarantees that the computed solution gives very small residual

This conclusion follows from the assumptions (1) and (2)

The factor (1) introduced in relation (2) is now equal to 2

The inequalities (1) are still adequate

We use this result without explicitly referring to the restriction (1)

Самое большее (меньшее)

... with a value at most of order one

$x$ differs from $y$ by at most 2

The longest edge is at most (at least) 10 times as long as the shortest one

$F$ has the most (fewest) points when...

What most interests us is whether...

The least such constant is called the norm of $A$

This is the least useful of the above four theorems

That is the least one can expect

These elements of $A$ are comparatively big but least in number

The best estimator is a linear combination $vee$ such that... is smallest possible

The expected waiting time is smallest if...

$L$ is the smallest number such that...

$K$ is the largest of the functions which occur in (3)

There exists a smallest algebra with this property

To find the second largest element in the list $L$

This model is at most (at least) a second-order approximation in $x$

Самое большее (меньшее)

... with a value at most of order one

$x$ differs from $y$ by at most 2

The longest edge is at most (at least) 10 times as long as the shortest one

$F$ has the most (fewest) points when...

What most interests us is whether...

The least such constant is called the norm of $A$

This is the least useful of the above four theorems

That is the least one can expect

These elements of $A$ are comparatively big but least in number

The best estimator is a linear combination $vee$ such that... is smallest possible

The expected waiting time is smallest if...

$L$ is the smallest number such that...

$K$ is the largest of the functions which occur in (3)

There exists a smallest algebra with this property

To find the second largest element in the list $L$

This model is at most (at least) a second-order approximation in $x$