RU2015560C1 - Device for selecting elements of contour image - Google Patents

Abstract

FIELD: computer technology; automatics. SUBSTANCE: delay unit, pulse generator, commutator and counter are introduced into the device. EFFECT: improved precision of the device. 4 dwg

Description

 The invention relates to automation and computer technology and can be used to recognize and process visual information.

 A device for selecting elements of the image circuit, containing a television sensor, analog-to-digital Converter, delay units, adders, comparators, registers, a pulse generator and an OR element. This device is not intended for the selection of contour segments, its end and corner points, as well as branch points. In addition, it is difficult constructively.

 A parallel device for isolating the elements of the contour of the image, containing photodetector elements, logical elements 4I-NOT, 2-2-2-2I-4ILI, 2I, 2ILI and inverters. However, it is not intended to highlight endpoints or branch points.

 Closest to the proposed device is a device containing a matrix of photodetector elements, horizontal and vertical blocks, first and second delay blocks, a memory unit, an adder, a clock, groups of elements BAN and OR elements, the matrix of photodetector elements connected to the first and second blocks sweeps whose inputs are connected to a clock generator, the first and second delay unit are connected to the outputs of the second sweep block and a clock generator, inputs of the first and watts a swarm of groups of bans are connected to the clock generator, to the outputs of the first and second delay units and the second scan unit, the first OR element is connected to the outputs of the first group of bans, the second OR element is connected to the outputs of the second group of bans, the inputs of the memory block are connected to the outputs the first and second elements OR and the clock generator, the inputs of the adder are connected to the outputs of the memory unit and the clock generator. However, this device is not intended for the selection of end and corner points of the contour, as well as its branch points and their calculation.

 The purpose of the invention is the expansion of the functionality of the device due to the additional selection of end and corner points of the contour, as well as its branch points and their calculation.

 The goal is achieved in that in a device containing a matrix of photodetector elements connected to the first and second horizontal and vertical blocks, the inputs of which are connected to a clock generator, the first and second delay blocks, the inputs of which are connected to a clock generator and a second scan block the third delay unit, the inputs of which are connected to the second scan unit and the clock generator, an AND-OR type programmable logic matrix, whose inputs are connected to the outputs of the first of the second, third, and third scan units, a memory unit whose inputs are connected to the outputs of the programmable logic matrix and a clock generator, an adder whose inputs are connected to a memory block and a clock generator, a switch whose inputs are connected to the outputs of the programmable logic matrix and a clock generator pulses, a counter whose inputs are connected to the output of the switch and the clock generator.

 The novelty of the proposed device is that in order to expand the functionality it introduced a third delay unit, the inputs of which are connected to the second scan unit and the clock generator, the programmable logic matrix of the type AND-OR inputs of which are connected to the outputs of the first, second and third blocks sweep, a memory unit whose inputs are connected to the outputs of a programmable logic matrix and a clock generator, an adder whose inputs are connected to a memory block and a clock generator O pulses, the switch having inputs connected to the outputs of a programmable logic array and the clock generator, counter, inputs of which are connected to the output of the switch and the clock pulse generator.

 In FIG. 1 shows a block diagram of a device for selecting contour image elements; in FIG. 2 is a block diagram of a vertical block; in FIG. 3 is a block diagram of a programmable logic matrix; in FIG. 4 is a structural diagram of a photodetector array.

 A device for selecting contour image elements contains a matrix 1 of photodetector elements, horizontal and vertical blocks 2 and 3, respectively, a clock pulse generator 4, a first 5, a second 6 and a third 7 delay blocks, an AND-OR 8 programmable logic matrix, a memory block 9, an adder 10, a switch 11, a counter 12, a group of control inputs 13, outputs 14-26.

 Block 3 vertical scan contains the first 27, second 28, third 29 groups of analog keys, shift register 30, amplifiers-shapers 31, control input 32, inputs 33 and outputs 34, 35, 36.

 The vertical block operates as follows.

 With the successive occurrence of clock pulses at the control input 32, the shift register 30 alternately opens one of the key groups, thereby connecting the three horizontal buses 33 (bit buses of the photomatrix 1) to the output buses 34, 35, 36 through the amplifiers-shapers 31. The latter are used for matching photodetector matrix 1 (type MF-6, MF-14) with logic circuits (for example, with TTL circuits). Amplifiers-shapers 31 (type 1UI 692, K 170 UI2, K 170UI4, 2UI631, etc.) amplify and bring to standard TTL levels the signals from the discharge buses of the photodetector matrix, received through analog keys 27-29 (type K1KT682 )

 The AND-OR 8 programmable logic matrix (type 583 PT1, 556 PT1) contains the AND 37 matrix and the OR matrix 38, consisting of diodes 39, input buffers (amplifiers) 40, output buffers (amplifiers) 41, a group of inputs 42 and outputs 43- 59.

It operates as follows. The input buses 42 are supplied with variables x _about -x ₈ over which the matrix AND 37 performs conjunction operations. The variables x _o -x ₈ correspond to the elements of the 3 x 3 window of the photodetector matrix onto which the image is projected, with x _o = = s (i, j); x ₁ = s (i-1, j); x ₂ = s (i-1, j + 1); x ₃ = s (i, j + 1); x ₄ = s (i + 1, j + 1); x ₅ = s (i + 1, j); x ₆ = s (i + 1, j-1); x ₇ = s (i, j-1); x ₈ = s (i-1, j-1), where s (.) are the image elements in the 3 x 3 window. The required logical products are formed on the column buses by burning out unnecessary jumpers - diodes 39 between rows and columns. The matrix OR 38 performs disjunction operations on logical products formed by the matrix AND 37. The programming of the matrix OR 38 is carried out similarly to the programming of the matrix AND 37. At the outputs of the matrix OR 38 amplifiers 41 are placed that transmit the value of the output functions f ₁ -f ₁₇ to the output buses 43-59 respectively. To match the matrix inputs (for example, with TTL circuits) buffer amplifiers 40 are used.

→

x

x

x

→

x

x

x

→

x₈), при выделении вертикальных отрезков на выходе 44 имеют высокий уровень функции
f₂= x₀x

x

, при выделении горизонтальных отрезков на выходе 45 имеют высокий уровень функции
f₃= x

x

x

, при выделении наклонных отрезков на выходах 45, 47 имеют высокий уровень функций соответственно
для левых
f₄= x

x

x₈,
для правых
f₅= x

x

x

, при выделении угловых точек контура на выходе 48 имеют высокий уровень функции
f₆= x₀(x₁x

x

x

x

x

→ x

x

x

x

x

x₈∨→
→

x₂x

x

x

x

x

→

x

x

x

x

x₃x

→

x

x

x

x

x

x₈∨→
→

x₄x

x

x

x₄x

x

→

x₅x

x

x

x₈∨→
→

x₆x

x

x

x₇x₈); при выделении точек ветвления на выходах 49-54 имеют высокий уровень функции соответственно для точек ветвления степени три
f₇= x₀(x₁x₂x

→ x₁x

x

x₁x

x

x₁x

x

→ x

x

x₆x

∨ x₁x

x₈∨x

x₃x

x₈∨x

x

x

→ x

x

x

→ x

x

x

x

x

x₈∨x

x₄x

→ x

x

x

→ x

x

x

x

x

x₈∨x

x₅x

∨ x

x

x

→ x

x

x₈∨x

x₆x

x

x

x₈∨→
→ x

x₇x

x₂x₃x

x₂x

x

→

x₂x

x

x₂x

x

x₂x

x₈∨→
→

x

x₄x

x

x

x

x

x

x

→

x

x

x

x

x₅x

x

x

x

→

x

x

x

x

x₆x

x

x

x₈∨→
→

x

x₇x

x₃x₄x

x₃x

x

→

x₃x

x

x₃x

x

x

x₅x

→

x

x

x

x

x

x

x

x₆x

→

x

x

x

x

x₇x

x₄x₅x

→

x₄x

x

x₄x

x

x

x₆x

→

x

x

x

x

x₇x

x₅x₆x

→

x₅x

x

x

x₇x

x₆x₇x₈), для точек ветвления степени четыре
f₈= x_o(x₁x₂x₃x

→ x₁x₂x

x

x₁x₂x

x

x₁x₂x

x

→ x₁x₂x

x₈∨x₁x

x₄x

x₁x

x

x

→ x₁x

x

x

x₁x

x

x₈∨x₁x

x₅x

→ x₁x

x

x

x₁x

x

x₈∨x₁x

x₆x

→ x₁x

x

x₈∨x₁x

x₇x₈∨x

x₃x₄x

→ x

x₃x

x

x

x₃x

x

x

x₃x

x₈∨→
→ x

x

x₅x

x

x

x

x

x

x

x

x₈∨→
→ x

x

x₆x

x

x

x

x₈∨x

x

x₇x₈∨→
→ x

x₄x₅x

x

x₄x

x

x

x₄x

x₈∨→
→ x

x

x₆x

x

x

x

x₈∨x

x

x₇x₈∨→
→ x

x₅x₆x

x

x₅x

x₈∨x

x

x₇x₈∨→
→ x

x₆x₇x

x₂x₃x₄x

x₂x₃x

x

→

x₂x₃x

x

x₂x₃x

x

x₂x

x₅x

→

x₂x

x

x

x₂x

x

x

x₂x

x₆x

→

x₂x

x

x

x₂x

x₇x

x

x₄x₅x

→

x

x₄x

x

x

x₄x

x

x

x

x₆x

→

x

x

x

x

x

x

x₇x

x

x₅x₆x

→

x

x₅x

x

x

x

x₇x

x

x₆x₇x₈∨→
→

x₃x₄x₅x

x₃x₄x

x

x₃x₄x

x₈∨→
→

x₃x

x₆x

x₃x

x

x

x₃x

x₇x₈∨→
→

x

x₅x₆x

x

x₅x

x

x

x

x₇x₈∨→
→

x

x₆x₇x

x₄x₅x₆x

x₄x₅x

x₈∨→
→

x₄x

x₇x

x

x₆x₇x

x₅x₆x₇x₈), для точек ветвления степени пять
f₉= x_o(x₁x₂x₃x₄x

→ x₁x₂x₃x

x

x₁x₂x₃x

x

x₁x₂x₃x

x₈∨→
→ x₁x₂x

x₅x

→ x₁x₂x

x

x

x₁x₂x

x

x₈∨x₁x₂x

x₆x

→ x₁x₂x

x

x₈∨→
→ x₁x₂x

x₇x₈∨x₁x

x₄x₅x

x₁x

x₄x

x

→ x₁x

x₄x

x₈∨→
→ x₁x

x

x₆x

x₁x

x

x

x₈∨x₁x

x

x₇x₈∨→
→ x₁x

x₅x₆x

→ x₁x

x₅x

x₈∨x₁x

x

x₇x₈∨x₁x

x₆x₇x₈∨→
→ x

x₃x₄x₅x

x

x₃x₄x

x

x

x₃x₄x

x₈∨→
→ x

x₃x

x₆x

x

x₃x

x

x₈∨x

x₃x

x₇x₈∨→
→ x

x

x₅x₆x

x

x

x₅x

x₈∨x

x

x

x₇x₈∨→
→ x

x

x₆x₇x₈∨x

x₄x₅x₆x

x

x₄x₅x

x₈∨→
→ x

x₄x

x₇x₈∨x

x

x₆x₇x₈∨x

x₅x₆x₇x₈∨→
→

x₂x₃x₄x₅x

x₂x₃x₄x

x

x₂x₃x₄x

x₈∨→
→

x₂x₃x

x₆x

x₂x₃x

x

x

x₂x₃x

x₇x₈∨→
→

x₂x

x₅x₆x

x₂x

x₅x

x

x₂x

x

x₇x₈∨→
→

x₂x

x₆x₇x

x

x₄x₅x₆x

x

x₄x₅x

x₈∨→
→

x

x₄x

x₇x

x

x

x₆x₇x

x

x₅x₆x₇x₈∨→
→

x₃x₄x₅x₆x

x₃x₄x₅x

x

x₃x₄x

x₇x₈∨→
→

x₃x

x₆x₇x

x

x₅x₆x₇x

x₄x₅x₆x₇x₈), для точек ветвления степени шесть
f₁₀= x_o(

x₃x₄x₅x₆x₇x₈∨→
→

x

x₄x₅x₆x₇x

x₂x

x₅x₆x₇x

x₂x₃x

x₆x₇x₈∨→ →

x₂x₃x₄x

x₇x

x₂x₃x₄x₅x

x

x₂x₃x₄x₅x₆x

→ x

x₄x₅x₆x₇x₈∨x

x

x₅x₆x₇x₈∨x

x₃x

x₆x₇x₈∨→
→ x

x₃x₄x

x₇x₈∨x

x₃x₄x₅x

x₈∨x

x₃x₄x₅x₆x

→ x₁x

x₅x₆x₇x₈∨x₁x

x

x₆x₇x₈∨x₁x

x₄x

x₇x₈∨→
→ x₁x

x₄x₅x

x₈∨x₁x

x₄x₅x₆x

x₁x₂x

x₆x₇x₈∨→
→ x₁x₂x

x

x₇x₈∨x₁x₂x

x₅x

x₈∨x₁x₂x

x₅x₆x

→ x₁x₂x₃x

x₇x₈∨x₁x₂x₃x

x

x₈∨x₁x₂x₃x

x₆x

→ x₁x₂x₃x₄x

x₈∨x₁x₂x₃x₄x

x

x₁x₂x₃x₄x₅x

) , для точек ветвления степени семь
f₁₁= x₀(

x₂x₃x₄x₅x₆x₇x₈∨→
→ x

x₃x₄x₅x₆x₇x₈∨x₁x

x₄x₅x₆x₇x₈∨x₁x₂x

x₅x₆x₇x₈∨→ → x₁x₂x₃x

x₆x₇x₈∨x₁x₂x₃x₄x₅x

x₈∨x₁x₂x₃x₄x

x₇x₈∨→ → x₁x₂x₃x₄x₅x₆x

), для точек ветвления степени восемь
f₁₂ = x_ox₁x₂x₃x₄x₅x₆x₇x₈, при выделении точки на выходе 55 имеют высокий уровень функции
f₁₃= x

, функции анализируют состояние четырех элементов в левом верхнем углу окно 3 х 3 : x_o, x₁, x₇, x₈, причем горизонтальному отрезку соответствует высокий уровень на выходе 56 функции
f₁₄ = x_ox₇, вертикальному отрезку соответствует высокий уровень на выходе 57 функции
f₁₅ = x_ox₁, наклонному отрезку соответствует высокий уровень на выходах 58, 59 функций соответственно для левого
f₁₆ = x_ox₈,
для правого
f₁₇ = x₁x₇.The AND-OR 8 programmable logic matrix implements the following Boolean functions: when the end points of the contour are selected, output 43 has a high level of function
f ₁ = x ₀ (x

→

x

x

x

→

x

x

x

→

x ₈ ), when highlighting vertical segments at output 44, they have a high level of function
f ₂ = x ₀ x

x

, when highlighting horizontal segments at the output 45 have a high level of function
f ₃ = x

x

x

, when highlighting the inclined segments at the outputs 45, 47 have a high level of functions, respectively
for the left
f ₄ = x

x

x ₈
for the right
f ₅ = x

x

x

, when highlighting the corner points of the circuit at the output 48 have a high level of function
f ₆ = x ₀ (x ₁ x

x

x

x

x

→ x

x

x

x

x

x ₈ ∨ →
→

x ₂ x

x

x

x

x

→

x

x

x

x

x ₃ x

→

x

x

x

x

x

x ₈ ∨ →
→

x ₄ x

x

x

x ₄ x

x

→

x ₅ x

x

x

x ₈ ∨ →
→

x ₆ x

x

x

x ₇ x ₈ ); when selecting branch points at outputs 49-54, they have a high level of function, respectively, for branch points of degree three
f ₇ = x ₀ (x ₁ x ₂ x

→ x ₁ x

x

x ₁ x

x

x ₁ x

x

→ x

x

x ₆ x

∨ x ₁ x

x ₈ ∨x

x ₃ x

x ₈ ∨x

x

x

→ x

x

x

→ x

x

x

x

x

x ₈ ∨x

x ₄ x

→ x

x

x

→ x

x

x

x

x

x ₈ ∨x

x ₅ x

∨ x

x

x

→ x

x

x ₈ ∨x

x ₆ x

x

x

x ₈ ∨ →
→ x

x ₇ x

x ₂ x ₃ x

x ₂ x

x

→

x ₂ x

x

x ₂ x

x

x ₂ x

x ₈ ∨ →
→

x

x ₄ x

x

x

x

x

x

x

→

x

x

x

x

x ₅ x

x

x

x

→

x

x

x

x

x ₆ x

x

x

x ₈ ∨ →
→

x

x ₇ x

x ₃ x ₄ x

x ₃ x

x

→

x ₃ x

x

x ₃ x

x

x

x ₅ x

→

x

x

x

x

x

x

x

x ₆ x

→

x

x

x

x

x ₇ x

x ₄ x ₅ x

→

x ₄ x

x

x ₄ x

x

x

x ₆ x

→

x

x

x

x

x ₇ x

x ₅ x ₆ x

→

x ₅ x

x

x

x ₇ x

x ₆ x ₇ x ₈ ), for branch points of degree four
f ₈ = x _o (x ₁ x ₂ x ₃ x

→ x ₁ x ₂ x

x

x ₁ x ₂ x

x

x ₁ x ₂ x

x

→ x ₁ x ₂ x

x ₈ ∨x ₁ x

x ₄ x

x ₁ x

x

x

→ x ₁ x

x

x

x ₁ x

x

x ₈ ∨x ₁ x

x ₅ x

→ x ₁ x

x

x

x ₁ x

x

x ₈ ∨x ₁ x

x ₆ x

→ x ₁ x

x

x ₈ ∨x ₁ x

x ₇ x ₈ ∨x

x ₃ x ₄ x

→ x

x ₃ x

x

x

x ₃ x

x

x

x ₃ x

x ₈ ∨ →
→ x

x

x ₅ x

x

x

x

x

x

x

x

x ₈ ∨ →
→ x

x

x ₆ x

x

x

x

x ₈ ∨x

x

x ₇ x ₈ ∨ →
→ x

x ₄ x ₅ x

x

x ₄ x

x

x

x ₄ x

x ₈ ∨ →
→ x

x

x ₆ x

x

x

x

x ₈ ∨x

x

x ₇ x ₈ ∨ →
→ x

x ₅ x ₆ x

x

x ₅ x

x ₈ ∨x

x

x ₇ x ₈ ∨ →
→ x

x ₆ x ₇ x

x ₂ x ₃ x ₄ x

x ₂ x ₃ x

x

→

x ₂ x ₃ x

x

x ₂ x ₃ x

x

x ₂ x

x ₅ x

→

x ₂ x

x

x

x ₂ x

x

x

x ₂ x

x ₆ x

→

x ₂ x

x

x

x ₂ x

x ₇ x

x

x ₄ x ₅ x

→

x

x ₄ x

x

x

x ₄ x

x

x

x

x ₆ x

→

x

x

x

x

x

x

x ₇ x

x

x ₅ x ₆ x

→

x

x ₅ x

x

x

x

x ₇ x

x

x ₆ x ₇ x ₈ ∨ →
→

x ₃ x ₄ x ₅ x

x ₃ x ₄ x

x

x ₃ x ₄ x

x ₈ ∨ →
→

x ₃ x

x ₆ x

x ₃ x

x

x

x ₃ x

x ₇ x ₈ ∨ →
→

x

x ₅ x ₆ x

x

x ₅ x

x

x

x

x ₇ x ₈ ∨ →
→

x

x ₆ x ₇ x

x ₄ x ₅ x ₆ x

x ₄ x ₅ x

x ₈ ∨ →
→

x ₄ x

x ₇ x

x

x ₆ x ₇ x

x ₅ x ₆ x ₇ x ₈ ), for branch points of degree five
f ₉ = x _o (x ₁ x ₂ x ₃ x ₄ x

→ x ₁ x ₂ x ₃ x

x

x ₁ x ₂ x ₃ x

x

x ₁ x ₂ x ₃ x

x ₈ ∨ →
→ x ₁ x ₂ x

x ₅ x

→ x ₁ x ₂ x

x

x

x ₁ x ₂ x

x

x ₈ ∨x ₁ x ₂ x

x ₆ x

→ x ₁ x ₂ x

x

x ₈ ∨ →
→ x ₁ x ₂ x

x ₇ x ₈ ∨x ₁ x

x ₄ x ₅ x

x ₁ x

x ₄ x

x

→ x ₁ x

x ₄ x

x ₈ ∨ →
→ x ₁ x

x

x ₆ x

x ₁ x

x

x

x ₈ ∨x ₁ x

x

x ₇ x ₈ ∨ →
→ x ₁ x

x ₅ x ₆ x

→ x ₁ x

x ₅ x

x ₈ ∨x ₁ x

x

x ₇ x ₈ ∨x ₁ x

x ₆ x ₇ x ₈ ∨ →
→ x

x ₃ x ₄ x ₅ x

x

x ₃ x ₄ x

x

x

x ₃ x ₄ x

x ₈ ∨ →
→ x

x ₃ x

x ₆ x

x

x ₃ x

x

x ₈ ∨x

x ₃ x

x ₇ x ₈ ∨ →
→ x

x

x ₅ x ₆ x

x

x

x ₅ x

x ₈ ∨x

x

x

x ₇ x ₈ ∨ →
→ x

x

x ₆ x ₇ x ₈ ∨x

x ₄ x ₅ x ₆ x

x

x ₄ x ₅ x

x ₈ ∨ →
→ x

x ₄ x

x ₇ x ₈ ∨x

x

x ₆ x ₇ x ₈ ∨x

x ₅ x ₆ x ₇ x ₈ ∨ →
→

x ₂ x ₃ x ₄ x ₅ x

x ₂ x ₃ x ₄ x

x

x ₂ x ₃ x ₄ x

x ₈ ∨ →
→

x ₂ x ₃ x

x ₆ x

x ₂ x ₃ x

x

x

x ₂ x ₃ x

x ₇ x ₈ ∨ →
→

x ₂ x

x ₅ x ₆ x

x ₂ x

x ₅ x

x

x ₂ x

x

x ₇ x ₈ ∨ →
→

x ₂ x

x ₆ x ₇ x

x

x ₄ x ₅ x ₆ x

x

x ₄ x ₅ x

x ₈ ∨ →
→

x

x ₄ x

x ₇ x

x

x

x ₆ x ₇ x

x

x ₅ x ₆ x ₇ x ₈ ∨ →
→

x ₃ x ₄ x ₅ x ₆ x

x ₃ x ₄ x ₅ x

x

x ₃ x ₄ x

x ₇ x ₈ ∨ →
→

x ₃ x

x ₆ x ₇ x

x

x ₅ x ₆ x ₇ x

x ₄ x ₅ x ₆ x ₇ x ₈ ), for branch points of degree six
f ₁₀ = x _o (

x ₃ x ₄ x ₅ x ₆ x ₇ x ₈ ∨ →
→

x

x ₄ x ₅ x ₆ x ₇ x

x ₂ x

x ₅ x ₆ x ₇ x

x ₂ x ₃ x

x ₆ x ₇ x ₈ ∨ → →

x ₂ x ₃ x ₄ x

x ₇ x

x ₂ x ₃ x ₄ x ₅ x

x

x ₂ x ₃ x ₄ x ₅ x ₆ x

→ x

x ₄ x ₅ x ₆ x ₇ x ₈ ∨x

x

x ₅ x ₆ x ₇ x ₈ ∨x

x ₃ x

x ₆ x ₇ x ₈ ∨ →
→ x

x ₃ x ₄ x

x ₇ x ₈ ∨x

x ₃ x ₄ x ₅ x

x ₈ ∨x

x ₃ x ₄ x ₅ x ₆ x

→ x ₁ x

x ₅ x ₆ x ₇ x ₈ ∨x ₁ x

x

x ₆ x ₇ x ₈ ∨x ₁ x

x ₄ x

x ₇ x ₈ ∨ →
→ x ₁ x

x ₄ x ₅ x

x ₈ ∨x ₁ x

x ₄ x ₅ x ₆ x

x ₁ x ₂ x

x ₆ x ₇ x ₈ ∨ →
→ x ₁ x ₂ x

x

x ₇ x ₈ ∨x ₁ x ₂ x

x ₅ x

x ₈ ∨x ₁ x ₂ x

x ₅ x ₆ x

→ x ₁ x ₂ x ₃ x

x ₇ x ₈ ∨x ₁ x ₂ x ₃ x

x

x ₈ ∨x ₁ x ₂ x ₃ x

x ₆ x

→ x ₁ x ₂ x ₃ x ₄ x

x ₈ ∨x ₁ x ₂ x ₃ x ₄ x

x

x ₁ x ₂ x ₃ x ₄ x ₅ x

), for branch points of degree seven
f ₁₁ = x ₀ (

x ₂ x ₃ x ₄ x ₅ x ₆ x ₇ x ₈ ∨ →
→ x

x ₃ x ₄ x ₅ x ₆ x ₇ x ₈ ∨x ₁ x

x ₄ x ₅ x ₆ x ₇ x ₈ ∨x ₁ x ₂ x

x ₅ x ₆ x ₇ x ₈ ∨ → → x ₁ x ₂ x ₃ x

x ₆ x ₇ x ₈ ∨x ₁ x ₂ x ₃ x ₄ x ₅ x

x ₈ ∨x ₁ x ₂ x ₃ x ₄ x

x ₇ x ₈ ∨ → → x ₁ x ₂ x ₃ x ₄ x ₅ x ₆ x

), for branch points of degree eight
f ₁₂ = x _o x ₁ x ₂ x ₃ x ₄ x ₅ x ₆ x ₇ x ₈ , when highlighting the points at the output 55 have a high level of function
f ₁₃ = x

, the functions analyze the state of the four elements in the upper left corner of the 3 x 3 window: x _o , x ₁ , x ₇ , x ₈ , and the horizontal segment corresponds to a high level at the output of 56 functions
f ₁₄ = x _o x ₇ , the vertical segment corresponds to a high level at the output of 57 functions
f ₁₅ = x _o x ₁ , the inclined segment corresponds to a high level at the outputs of 58, 59 functions, respectively, for the left
f ₁₆ = x _o x ₈ ,
for the right
f ₁₇ = x ₁ x ₇ .

 Horizontal scan unit 2 is an (N + 1) -bit shift register, at the outputs of which, under the influence of signals from a clock generator, a high level alternately appears.

 The first 5, second 6 and third 7 delay blocks are three-digit shift registers.

 The circuit of the switch 11 is similar to the circuit K155KP7.

)) и шины стирания, например, из положительной ТТЛ-логики в отрицательную логику МДП-схем фотоматрицы. В качестве сигнала стирания информации фотоматрицы может использоваться импульс с (N+1)-го разряда блока 2 горизонтальной развертки или внешний сигнал стирания, подаваемый перед записью новой информации. Каждая фотоприемная ячейка 60 фотоматрицы содержит фотодиод Д и три МДП-транзистора Т₁, Т₂, Т₃. Транзистор Т₁ используется для стирания информации, транзистор 2 - в качестве усилителя, а транзистор Т₃ - для адресации ячейки. Стирание информации осуществляется подачей отпирающего напряжения на затвор транзистора Т₁. При этом барьерная емкость фотодиода Д, смещенного в обратном направлении, заряжается до напряжения питания E_п2. В течение времени записи емкость фотодиода разряжается либо фототоком, либо темновым током диода. Перепад напряжения на фотодиоде модулирует сопротивление канала транзистора Т₂. В течение времени считывания информация, записанная в фотоячейки, считывается отпирающим напряжением, подаваемым на затворы транзисторов Т₃. При этом высокому уровню оптического сигнала на входе ячейки соответствует низкий уровень выходного сигнала на разрядной шине РШ_i ((i=

))и наоборот.The photodetector matrix 1 contains photodetector cells 60 and level converters 61, which convert the signals of address buses ASh _i ((i =

)) and the erase bus, for example, from the positive TTL logic to the negative logic of the MIS schemes of the photomatrix. As a signal for erasing the information of the photomatrix, a pulse from the (N + 1) -th discharge of the horizontal scanning unit 2 or an external erasure signal supplied before recording new information can be used. Each photodetector cell 60 of the photomatrix contains a photodiode D and three MOS transistors T ₁ , T ₂ , T ₃ . Transistor T _{1 is} used to erase information, transistor 2 is used as an amplifier, and transistor T ₃ is used to address a cell. Erasing information is carried out by applying a trigger voltage to the gate of the transistor T ₁ . In this case, the barrier capacitance of the photodiode D, biased in the opposite direction, is charged to the supply voltage E _p2 . During the recording time, the capacitance of the photodiode is discharged either by the photocurrent or by the dark current of the diode. The voltage drop across the photodiode modulates the channel resistance of the transistor T ₂ . During the reading time, the information recorded in the photocell is read by the unlocking voltage supplied to the gates of the transistors T ₃ . At the same time, a high level of the optical signal at the input of the cell corresponds to a low level of the output signal on the discharge bus RSh _i ((i =

))and vice versa.

 A device for selecting elements of a contour image operates as follows.

)) фотоприемной матрицы 1, в результате чего на ее разрядных шинах РШ_i ((i=

)) имеется сигнал, соответствующий состоянию фотоэлементов выбранной адресной шины. Блок 3 вертикальной развертки поочередно подключает тройки разрядных шин фотоматрицы 1 к блокам 5, 6 и 7 задержки. На выходах блоков задержки имеют в первых разрядах сигнала от трех соседних элементов, развертываемых в данный момент t, во втором от трех элементов, развертываемых в момент времени t-1, в третьем от трех элементов, развертываемых в момент времени t-2, в результате чего реализуется бегущее окно 3х3 из девяти элементов. Сигналы с выходов блоков 5, 6, 7 задержки поступают на входы программируемой логической матрицы И-ИЛИ 8, которая по ним формирует выходные сигналы, позволяющие определять характер центральной точки окна.The outline image is projected onto the matrix 1 of photodetector elements. Block 2 horizontal scan alternately drives the address bus ASh _i ((i =

)) of the photodetector matrix 1, as a result of which on its discharge buses FS _i ((i =

)) there is a signal corresponding to the state of the photocells of the selected address bus. The vertical scanning unit 3 alternately connects the triples of the discharge buses of the photomatrix 1 to the delay units 5, 6, and 7. At the outputs of the delay blocks, in the first bits of the signal from three neighboring elements being deployed at the moment t, in the second from three elements being deployed at time t-1, in the third from three elements being deployed at time t-2, as a result of which a 3x3 running window of nine elements is realized. The signals from the outputs of blocks 5, 6, 7 of the delay are fed to the inputs of a programmable logic matrix AND-OR 8, which from them generates output signals that allow you to determine the nature of the center point of the window.

 If only the central element of the window is lit, then a point is fixed and at the output 26 they are at a high level; if, in addition to the central element, one, two, three, four, five, six, seven or eight elements are lit, then terminal, angular, branches of degree three are fixed , degrees four, degrees five, degrees six, degrees seven and degrees eight points and at outputs 14, 19-25 have a high signal level, respectively, except when only three diagonal elements are lit. In this case, either the right or left inclined segment is fixed and, at the output 16 or 18, respectively, have a high level. Similarly, if the elements of the central column or center row are illuminated, a vertical or horizontal segment is fixed and, at the output 15 or 17, respectively, have a high signal level.

 The output buses 14-26 are connected to the information inputs of the switch 11, which, depending on the applied control signal, connects the selected bus to the counter 12, thereby allowing selective counting of the allocated points.

при наличии горизонтального или вертикального участка, на соответствующих выходах блока памяти присутствует сигнал кода 1, которые суммируются в сумматоре 10. В результате в сумматоре получают значение, пропорциональное периметру контурного изображения.The signals from the outputs 54-57 of the programmable logic matrix, generated by the results of the four upper left window elements, are fed to the address inputs of the memory unit 9. In the case of an inclined portion of the image, a code signal is present at the output of the memory block

in the presence of a horizontal or vertical section, at the corresponding outputs of the memory block there is a signal of code 1, which are summed in the adder 10. As a result, a value proportional to the perimeter of the contour image is obtained in the adder.

In contrast to the known devices, the proposed additionally distinguishes end, angular, branch points of degree three, degree four, degree five, degree six, degree seven and degree eight. Thus, the functionality has expanded approximately 5 times. Moreover, the device contains 1.2-2 times more elements (diodes, transistors) in comparison with the known ones. Indeed, the proposed device contains approximately L '≈ 14N ² + 10 ³ elements, and the known (prototype) contains L' ≈ 12N ² , where NxN is the image size. Therefore, at N = 32 - 1024, they get L / L '≈ 1.2-2.

Claims (1)

 DEVICE FOR SELECTION OF CONTOUR IMAGES, containing a photodetector array, the outputs of which are connected to the inputs of the vertical scan unit, the first and second outputs of which are connected respectively to the information inputs of the first and second delay units, the outputs of which are connected respectively to the first and second groups of inputs of a logical matrix of the type AND-OR, the first group of outputs of which is connected to the information inputs of the memory block, the outputs of which are connected to the information inputs of the adder, block horizontal scan, the outputs of which are connected to the inputs of the matrix of photodetector elements, characterized in that, in order to increase the accuracy of the device by additionally selecting the ring and corner points of the contour, branch points and expanding functionality by selectively counting the length of the segments, a third delay block is introduced into it, pulse generator, switch and counter, the output of the pulse generator is connected to the synchro inputs of horizontal and vertical blocks, the first to third delay blocks, bl As for the memory, adder, switch, and counter, the information input of the third delay block is connected to the third output of the vertical scan unit, and the outputs are connected to the third group of inputs of the AND-OR logic matrix, the second group of outputs of which is connected to the signal inputs of the switch and is the first group of information device outputs, the output of the switch is connected to the counting input of the counter, the outputs of which are the second group of information outputs of the device, the control inputs of the switch are control inputs and devices.

Images