RO121950B1 - Electronic generator of complex functions with multiple channels galvanically isolated and with synchronous or asynchronous functioning - Google Patents

Abstract

The invention relates to an electronic generator of complex functions with a number of independent channels, galvanically isolated, which, at the output of each channel, generates an electronic signal as wave, frequency, amplitude and synchronous and asynchronous way of functioning, digitally programmable depending on the command. According to the invention, the generator comprises a supplying module (B1) which provides the current and the continuous voltage needed for charging a backup battery (BT1) and the current and the functioning voltage, respectively, a module (C1) for loading/controlling the backup battery (BT1), which provides the automatic control of the current and the voltage charging/discharging a rechargeable battery, a module (MC) of control, centrally equipped with a microprocessor, coupled by an input cable (USB) with a LAPTOP/PALM and an output flat cable, of Local Bus type, with a sufficient number of conductors, with a number of complex functions generating modules (MG1...MG32) each coupled to the same flat cable of Local Bus type as the central module (MC) and which generates, at the output of each, an electric signal as a complex function of wave, frequency, amplitude, the sample period has also programmable output power and which functions on the basis of some specialized soft programs installed on an external support specific to the operation systems of a LAPTOP/PALM, transferrable to the central control module (MC) and to the modules (MG1...MG32) generating complex functions, respectively.

Description

The invention relates to an electronic generator of complex functions with multiple channels, galvanically isolated from each other and with synchronous or asynchronous operation, which generates at the output of each channel an electrical signal with waveform, frequency, amplitude and synchronous or asynchronous programmable mode of operation digital according to the data received from a LATOP / PALM equipped with a specialized software package.

Different devices or function generators are known that provide such functions on one or more channels, depending on the purpose of use. Typically, these devices are designed to work either as standard function generators, with limited possibilities regarding the type of programmed and generated functions or the number of output channels or the type of applications.

The technical problem that the invention solves is to obtain a number of complex functions, with synchronous or asynchronous mode of operation, digitally programmable.

The system according to the invention removes the disadvantages mentioned above by having in its composition a power module that provides the current and the continuous voltage required to charge a rechargeable battery and respectively the operating voltage and voltage of the electronic generator of complex functions, a charging module / rechargeable battery monitoring that ensures automatic control of the current and charging / discharging voltage of the rechargeable battery, a central control module, equipped with a microprocessor, which provides the data connection on an input with the output of an external LAPTOP / PALM and respectively through a Local Bus output ribbon cable, with a sufficient number of conductors, with a number of modules generating complex functions, each coupled to the same Local Bus ribbon cable as the central module and which generates, at the output of each, a electrical signal in the form of a com function Plexuses with waveform, frequency, amplitude, sampling duration and output power programmable and operating on the basis of specialized software programs, installed on an external support specific to the operating systems of a LAPTOP / PALM, transferable to the central module and respectively modules that generate complex functions.

The invention has the advantage that it allows to obtain a number of complex functions, with synchronous or asynchronous mode of operation, digitally programmable.

The following is an example of an embodiment of the invention in connection with FIG. 1 ... 8 which represents:

FIG. 1, block diagram of the programmable electronic generator of complex functions;

FIG. 2, the electrical diagram of the battery charging / monitoring module of the back-up battery with Li-lon;

FIG. 3, the electrical diagram of the central control and control module;

FIG. 4, the electrical diagram of the module (channel) generated by complex programmable functions;

FIG. 5, an example of a generable function with related parameters, programmable;

FIG. 6, the logic diagram of the operating program of the microprocessor for each channel;

FIG. 7, the logic diagram of the microprocessor operating program for the central command and control module;

FIG. 8, the control / selection and display interface of the programmable electronic generator, present on LAPTOP / PALM.

in FIG. 1 shows the block diagram of the programmable electronic generator of complex functions, according to the invention, where A1 represents the supply voltage of 90 ... 264V / 50 (60) Hz of the electrical source B1 with the output of DC voltage stabilized D1 of the type of LAPTOP power supplies. A C1 module for charging / monitoring a Li-lon type battery pack, which provides continuous voltage supply of the component modules of the generator according to the invention, and which, in addition,

RO 121950 Β1 limits the charging current, the maximum charge voltage of the battery pack and 1 respectively automatically disconnects the battery pack when its voltage reaches the minimum required level, a central MC command and control module equipped with a microprocessor that provides 3 data link on a D3 input with the USB output of an external LAPTOP / PALM CE and on the D4 output, of the Local Bus type, it provides continuous current supply and 5 commands and data exchanges respectively with the modules generating complex functions MG 1 ... MG32, coupled in parallel to the output D4, each generating at the output the electrical signals S1 .. .S32 7 which contain the complex functions generated.

in FIG. 2 shows the electrical diagram of module C1, according to the invention, where the presence of DC voltage, delivered by module B1, is displayed by LED D1, through which the current in the circuit formed by the resistor R1 and the diode of the optocoupler OC1 circulates. The 11-charge circuit of the BT1 battery pack is made by means of the D2 direction diode, the R2 measurement resistance of the charging / consumption current, the transistor Q1 of the 13 maximum charge / consumption current limit, the Darlington power transistor Q2, which ensures the control of the value of the charge / consumption current, the circuit of detection of the voltage of 15 battery of the BT1 battery, formed by the diode Zener D4, the potentiometer R5, the LED diode D3, the optotransistor of OC, the transistor Q3 and its collector circuit formed by the resistance 17 R3 , diode D7 and resistor R4. The presence of the optotransistor OC1 in the charging voltage measurement circuit means that in the absence of charging the battery or disconnecting the battery when the minimum voltage is reached 19 there are no other electrical charges connected to the BT1 battery terminals that would maintain the battery discharge current even after disconnection 21 automatic. The manual coupling circuit and automatic decoupling of the BT1 battery at the output load is carried out using the manual switch S1, which in the OFF state maintains the 23 discharged capacitor C1, and when switched to the ON state provides the power supply voltage in the transmitter of the Darlington Q4 power transistor. and, via the load current 25 of C1, controls the opening of the transistor Q5, which, in turn, provides the basic current required for the opening of Q4, through the resistor R6, if the voltage 27 at the output of Q4 is large enough to keep it open. the circuit consisting of the Zener D6 diode, the LED diode D5, which signals the presence of the supply voltage to modules 29 MG1 ... MG32, and the potentiometer R7. In case the voltage of the BT1 battery drops below the limit selected with the help of R7 and controlled by D6, then the transistor Q5 starts to lock 31, also causing the blockage of Q4 and, finally, the definitive blocking of Q4 and Q5.

in FIG. 3 shows the electrical diagram of the MC central mode according to the invention, which comprises a U1 microprocessor, which can be of type PIC16C745 manufactured by MICROCHIP, an input circuit for the USB connection with LAPTOP / PALM, formed by the USB connector. , J1, where the D +, D- data exchange connections between U1 and J1 are ensured, a circuit for detecting the presence of this USB connection with LAPTOP / PALM formed by transistor Q6, 37 polarization resistors R8, R9, collector resistance R10, resistor R11 and capacitor C4, a CLOCK signal forming circuit made with quartz Y1, capacitors C2, C3 39 and resistor R12, capacitors C5, C6 for filtering U1's power supply, a manual reset circuit of of U1, consisting of resistor R39 and button S2, a voltage stabilizer circuit 41 which provides at the output the voltage required for the operation of the microprocessor U1, formed by the specialized stabilizer circuit U2, the capacitors being Ltraj C7, C8, C9, C10 and connector 43 J3 for coupling DC input voltage and current amplifiers Q7.

.Q19, connect between the outputs of U1 and the actual output controls STBY, OP, LOCAL, 45 CENTRAL, MODE1, MODE2, TX, S1, S2, S3, S4, S5, S6. The command and control link of the MC module with the generator modules MG1 ... MG32, is realized through 47 of a 26-pin J2 connector of which 16 pins are used for command and control, and 10 are used to ensure the supply voltage. MG1 module power supply .. .MG32. Connector 49

J2 is mounted on a 26-wire ribbon cable that forms the Local Bus.

RO 121950 Β1 in fig. 4 presents the wiring diagram of a complex function generator module noted with MG1, MG1 modules. .MG32 having the identical hardware configuration, which includes optical isolation circuits of the MC inputs, denoted by U3, U4, U5, U6, U8 , U9, U10 and respectively the output of the MG1 module noted with U7, a microprocessor U11, an analog digital converter (DAC) with positive and negative output U12, a digital potentiometer U13, a repeater amplifier circuit U14, a final signal amplification circuit. positive or negative generated U15, a circuit for measuring the instantaneous value of current, voltage, active power, reactive power, apparent power, frequency, active energy, reactive and apparent delivered to the external electrical circuit, U16, a DC-DC converter consisting of U17, D14, C52, R98, C53, Tr, rectifiers V1, V2, V3, V4, voltage stabilizing circuits U18, U19, U20 and filter capacitors C54, C55, C56, C57, C58, C59, C60, at of which i outputs are generated continuous voltages of +/- 28Vcc, +/- 12Vcc and + 5Vcc, which provides the voltages necessary for the operation of the MG1 module and respectively ensures the galvanic isolation from the MC, the MG1 modules ... MG32 and the supply module C1, a circuit of automatic resetting of the potentiometer on the supply voltage coupling consisting of R71, D8, D9, C31, and a manual selection circuit of the ID code of the MG1 module, which in the 32-channel example has 5 SW1 switches and which generates RF6 inputs, RF7, RGO, RG1, RG2 of the U11 microprocessor logic inputs 0 (ZERO voltage) or 1 (voltage + VDD) depending on the desired ID code (1 ... 32). The DAC converter, U12, selected by the CS command, receives at parallel inputs DB0 ... DB11 the numerical code corresponding to the desired analog output value that it accepts according to the status of the WR, LDAC inputs, and generates a signal, with a non-significant delay, at The Vout output, which is directly connected to the input A of the digital potentiometer U13, from which, by digital positioning of the cursor W, is applied, via the repeater amplifier U14, to the input of the final power amplifier U15, and after amplification appears at the OUT output of where the external electrical load is applied via the normally open contacts of relay K1 of resistor R94, where resistor R93 is shorted by the normally open contact of relay K1, and connector J5. In the conditions when the relay K1 is not connected, an electrical signal taken from the output of the repeater amplifier U14 is present at the output and which is present at the output by means of the series resistors R93 and R94.

When coupling the supply voltage of the MG1 module, the automatic reset circuit of the digital potentiometer U13 maintains the output of the cursor connected to the ground, avoiding the appearance of transient signals at the input of the final amplifier U15.

Similarly, at the MUTE input of the final amplifier, a permanent command for blocking its output signal is provided through resistors R84, R85, the command which is inhibited by the microprocessor by the RA1 command which cancels the MUTE command of the final amplifier.

In order to protect the output circuit in case of failure of the final amplifier U15 and respectively to disconnect this output, the relay K1 is used which is coupled and decoupled only at the RD1 control of the U11 microprocessor and in addition has a timed automatic decoupling command when the supply voltage is switched on of module MG1 made with circuit R92, D12, D13, C49. The coupling state of the relay is controlled by the U11 microprocessor by monitoring the RG3 input.

When the relay K1 is not switched on, the output of small amplitude signals used to determine transfer functions in specially selected external circuits can be generated.

in FIG. 5 shows an example of a generable function having the programmable parameters T1, T11, T2, T22, NI, N2, A1 (N1), A2 (N2) with the digital selection of the amplitude of the electrical output signal.

RO 121950 Β1 in fig. 6 presents the logic scheme of operation of the MG1 module, identical for 1 MG2 modules ... MG32, based on which the software program package of the MG1 microprocessor is built. 3

When coupling the supply voltage of the MG1 ... MG32 modules, the microprocessor (U20) has its own RESET procedure and provides conditions for automatic hardware reset of the control outputs 5 to the digital potentiometer (U2), the final amplifier (U4) and the relay. output which is maintained with the contacts normally open. 7 depending on the orders received from the central module (MC), the module's microprocessor

MG1 ... MG32 generates a series of its own logical variables which, together with the combination of 9 commands received from the central module, generates different modes of operation, such as: 11

Initial programming (Pl) MG1: STBY = 1 and OP = 0 and CENTRAL = 1 and LOCAL = 1 and

Model = 0 and Mode 2 = 0 and S6 = 0 and IDC = SW1 and PRO = 0; at the end of receiving the 13 programming data MG 1 makes PRO = 1 and sends the Soft READY signal to the MC;

Asynchronous start selection (PA) channel MG1: STBY = 0 and OP = 1 and LOCAL = 1 and 15 CENTRAL = 0 and Mode 1 = 0 and Mode 2 = 0 and IDC = SW1 and PRO = 1 and READY = 1 and the Soft command = START from MC and MG1 transmits to the MC the signal Soft = RUNNING1; 17

Signal Level Selection (SNS) and T1.T11.T2.T22 for MG1 on: STBY = 0 and

OP = 1 and LOCAL = 1 and CENTRAL = 0 and Mode 1 = 0 and Mode 2 = 0 and IDC = SW1 andPRO = 1 and there is 19 Soft = RUNNING1 signal followed by the instantaneous values of the current in the output circuit received from MG1; 21

Synchronous start selection (PSS) Simultana Mode 1 channel 1: STBY = 0 and OP = 1 and LOCAL = 0 and CENTRAL = 1 and Mode 1 = 1 and Mode 2 = 0 and S6 = 1 and PRO = 1 and Soft Command 23 START from the MC; MG1 runs a single cycle Τ1 + T11 + T2 + T22 and stops waiting for a new Soft START command from MC; 25

Sequential start selection (PSSQ) channel 1: normal output power (PSSQ1) = the output of the U4 power amplifier is used by relay relay REL: 27

STBY = 0 and OP = 1 and LOCAL = 0 and CENTRAL = 1 and Model = 0 and Mode 2 = 1 and IDC = SW1 and PRO = 1 and the START soft command from MC; 29

MG1 runs a single cycle Τ1 + T11 + T2 + T22 and stops waiting for a new Soft START command from MC;

Reduced output power (PSSQ2) = Repeater amplifier output is used

U3 by maintaining the relay in relay state REL: STBY = 0 and OP = 1 and LOCAL = 0 and 33 CENTRAL = 1 and MODE1 = 1 and MODE2 = 1 and IDC = SW1 and PRO = 1 and the START soft command from MC; 35

Switch off (OC) channel 1: STBY = 0 and OP = 1 and IDC = SW1 and the Soft command

MC's STOP; MG1 sets the output RG6 = 0 and RD1 = 0 and verifies that RG3 = 0; 37

General stop selection (GGC) channel 1-32: OP = 0 and S6 = 1 and CENTRAL = 1 and

MC's Soft STOP command; MG1 sets the output RG6 = 0 and RD1 = 0 and verifies that RG3 = 0; 39 within the initial programming (Pl), the central module (MC), transmits sequentially to each generator module MG1 ... MG32, the parameters required to generate a function, according to 41 fig. 5, respectively, the values of time durations T1, T11, T2, T22, the graph of function A1 (N1) and the graph of function A2 (N2), the values N1 and N2, where N1 and N2 represent the number of points, and A1 (N1) 43 and A2 (N2) represents the digital values for the desired signal level to be generated by the analog digital converter U1. 45 based on the time periods transmitted by the MC, each module MG1 ... MG32 calculates its values DT1 = T1 / N1, DT2 = T2 / N2 and T3 = T1 + T11 + T2 + T22, values that define the value of 47 generation steps. respectively the frequency of repetition of the desired function consisting of two signal forms, which can be positive or negative or one positive and one negative and which define the periodic form of the electrical signal to be generated.

RO 121950 Β1

After receiving the programming data, each MG1 ... MG32 module selected will transmit to the MC a soft signal that it has received the data and can proceed to the next module. At the end of the PI phase, the MC module will inform the user that it can proceed to the own generation of functions. based on this information, the user selects the asynchronous start (PA) for each channel separately from the ones used (MG1 ... MG32) and adjusts the amplitude and the time duration T1, T11, T2, T22 depending on the desired performances and the measured parameters from the output circuit and keeps all the channels used and set in asynchronous mode, from now on, the PSS or PSSQ1 / PSSQ2 synchronous operating modes can be selected or one or all channels can be switched off for later use with the same parameters already programmed.

in FIG. 7 presents the logic scheme of operation of the central module MC that receives from the user, via LAPTOP / PALM, the desired operating modes and generates at the output, to the modules MG1 ... MG32, the commands related to the operating mode selected by the user.

in FIG. 8 shows an example of the interface between the user, via LAPTOP / PALM, and the central control module MC, where several operating modes are distinguished, namely the one for choosing the operating mode, followed by the one for the individual programming of the MG1 modules. ..MG32, the display of the parameters generated by each module MG1 ... MG32, the display of the programmed waveform and the one effectively generated by each module MG1 ... MG32 in the corresponding external circuit and the general logic display of the how each channel MG1 works ... MG32.

claims

Claims (11)

1. Electronic generator of complex functions, characterized in that it has in its component a power supply module (B1) that provides the current and the continuous voltage required to charge a rechargeable battery (BT1) and the current and the operating voltage of the electronic function generator complex, a rechargeable battery charging / monitoring module (C1) that provides automatic control of the current and charging / discharging voltage of the rechargeable battery (BT1), a central control module (MC), equipped with a microprocessor (U1), which provides data connection on an input (D3) with the output (USB) of an external LAPTOP / PALM (EC) and respectively by a Local Bus type output cable, with a sufficient number of conductors, with a number of modules generators of complex functions (MG1 .. .MG32), each connected to the same Local Bus type cable as the central module (MC) and which generates, at each output ruia, an electrical signal in the form of a complex function with programmable waveform, frequency, amplitude, sampling duration and output power, and which works on the basis of specialized software programs, installed on an external support specific to the operating systems of a LAPTOP / PALM (CE), transferable to the central module (MC) and to the modules generating complex functions (MG1 ... MG32). 2. Electronic generator of complex functions as in claim 1, characterized in that it connects between the central module (MC) and the modules generating complex functions (MG1 ... MG32) by a ribbon cable with Local Bus function with a number sufficient electric conductors capable of providing both the power supply of the component modules of the complex function generator and the transmission / reception of data between the central module (MC) and each generator module (MG1 ... MG32) and which allows the modulation of the function generator in the purpose of obtaining a flexible configuration with a selectable number of modules generating complex type functions (MG1 ... MG32) between 2 or 4 or 8 or 16 or 32 or any other combination desired without affecting the overall operation of the function generator complex. RO 121950 Β1 3. Electronic generator of complex functions as in claim 1, characterized in that, in the module for monitoring the rechargeable battery charge (BT1), namely in the voltage monitoring circuit at the battery terminals made with a Zener 3 diode ( D4) encloses with this the optocoupler of an optocoupler (OC1) which is kept open for as long as there is a supply voltage at its output (Bl) and which blocks at 5 the disappearance of this supply voltage protecting the discharge of the battery in the absence of the supply voltage and in especially after the automatic disconnection of the battery if the minimum voltage limit 7 set by the Zener diode (D6) is reached. 4. Electronic generator of complex functions as in claims 1,2 and 3, characterized in that it uses for manual coupling and automatic decoupling of the rechargeable battery (BT1) at the Local Bus power circuits an electronic switch 11 (Q4). -Q5) whose coupling is done manually by means of the switch (S1) with two positions respectively (ON) and (OFF), where in the position (OFF) it maintains the capacitor (C1) in short-circuit mode, which allows the of couplings / decouplings is not limited by the charge state of the capacitor (C1), and in the state (ON) it simultaneously provides both the voltage in the emitter 15 (Q4) and the base (Q5) through the charging current of of (C1). 5. Electronic generator of complex functions as in claim 1, characterized in that it uses a central control module (MC) equipped with a microprocessor (U1) and a package of specialized programs that allow communication through a serial port (USB). 19 with an external LAPTOP / PALM (EC) from which it receives the waveform to be generated and the asynchronous, synchronous or measuring mode and which provides for the output of individual or centralized selection commands of the function generating modules together with logical commands for selecting the mode of operation of each function generator module, commands 23 transmitted by means of current amplifiers connected directly to the Local Bus type cable. 25 6. Electronic generator of complex functions as in claim 1, characterized in that it uses a number of modules of identical complex functions connected 27 each through a connector to the same Local Bus type cable from where they receive the power supply, together with the controls. logics generated by the central module (MC) and 29 respectively the serial communication circuit between each generator module (MG1 ... MG32) and the central module (MC), commands made through optoelectronic integrated circuits 31 (U3 ... U10) which provides galvanic isolation between the central module (MC) and the generator modules (MG1 ... MG32) and between each of the generator modules (MG1 ... MG32) respectively. 33 7. Electronic generator of complex functions as in claims 1 and 6, characterized in that each generator module is equipped with a microprocessor (U11), analog digital converter (U12) capable of generating positive and negative signals at a point of zero potential. , a digital potentiometer (U13) that accepts at the input positive and negative signals 37 generated by an analog digital converter (U12) and which provides at the output a digitally controlled position of the cursor (W), a repeater amplifier of the output signal of 39 digital potentiometer (U14), a final power amplifier (U15), a relay (K1) controlled and controlled by the microprocessor and whose contacts provide, in a normally open state, a 41 low-power test signal used by specialized external circuits and under relay conditions an amplified signal for other specific uses, a specialized circuit 43 (U16) for measuring voltage, ass ent, frequency, active, reactive and apparent power, active, reactive and apparent energy delivered to an external circuit, a selector switch of the hardware address of the generator module (SW1) and a circuit for generating the supply voltages (+/- 28Vdc, +/- 12Vdc, + 5Vdc) required for the operation of the generator module. 47 RO 121950 Β1 8. Electronic generator of complex functions as in claim 1, 5, 6 and 7, characterized in that it uses a Local Bus type cable that provides both the voltage supply circuits and the circuits related to digital controls and data transfer. between the central module (MC) and the generator modules (MG1 .. .MG32), and which allows a linear distribution of the modules located along the length of the ribbon cable or a combined network-type distribution where each portion of the ribbon cable can support the necessary connections for a defined number of generator modules. 9. Electronic generator of complex functions as in claims 1 and 5, characterized in that it uses a set of logical signals generated by a central module (MC), galvanically isolated from each other and isolated from (MC) and generator modules (MG1. ..MG32), by which it individually selects each generator module or all the generator modules (MG1 ... MG32) to which it transmits the desired operating mode which can be initial programming (P1), asynchronous operation (PA), selection sampling amplitude and duration (SNS), simultaneous synchronous operation (PSS), low power sequential synchronous operation (PSSQ1), simultaneous normal power synchronous operation (PSSQ2), individual shutdown of a generator channel (OC) , of general shutdown of all the generating channels (OGC) together with the transmission or reception of data between the central module (MC) and the generating modules of the type (MG1 ... MG32). 10. Electronic generator of complex functions as in claims 1 and 9, characterized in that it allows, with the aid of an analog digital converter (U12), to generate waveforms with positive or negative polarity, with sampling times (DT1, DT2) programmable by keeping the number of samples and changing the total duration of the desired waveform (T1, T2), using the time duration (T11, T22) necessary for the data exchange between the central module (MC) and the generating modules (MG1. ..MG32) and respectively with programmable amplitude, realized with the help of a digital potentiometer (U13), facilities that allow to realize some complex modulation functions imposed by the type of application. 11. Electronic generator of complex functions as in claims 1 and 7, characterized in that it allows the generation of reduced or amplified waveforms that it applies to an external circuit, as long as it measures in real time the voltage and frequency type parameters. applied, of the generated current and the value of its phase shift to the applied voltage, of the active, reactive and apparent power consumed, of the active, reactive and apparent electric power delivered to the external circuit, the parameters used to generate operating modes of the generator module together with the external circuit selected by the constant current type, constant power, active, reactive or apparent energy, totally delivered and limited.