WO2015174886A1 - Multi-functional diagnostic system - Google Patents

Abstract

A multi-functional diagnostic system relates to devices for diagnosing and repairing electronic and electrical circuits and systems. A common probe housing, the external structure of which resembles a multi-color ballpoint pen, is equipped with an output cable and contains: a standard probe/contact of a multimeter/oscilloscope, an inductive or magnetoresistive sensor for contactlessly measuring current, an electrometer or capacitive sensor for contactlessly measuring voltage potential, a thermocouple or thermoresistance, corresponding amplifiers of the signals of each channel, and a device for mechanical and electronic circuit switching. The system additionally includes a combined device comprising a power supply and power amplifier, which device can be used as an adjustable source of voltage/current, and as a power amplifier having adjustable amplitude and phase, the load of which may be a circuit to be diagnosed or a component to be diagnosed, and a sensor of the corresponding channel may be included in a feedback circuit. It is also possible to include a built-in loudspeaker in order to achieve the audio control of an output signal. Integrating the functions of the specified devices into a single device allows for increasing functionality and ease of use.

Description

 MULTIFUNCTIONAL DIAGNOSTIC COMPLEX

The utility model relates to the field of devices for measurement and diagnostics and can be used for diagnostics, repair and development of various electronic and

electrical devices and circuits.

The level of technology.

Known:

 (1) Millivoltmeters with an active probe, in which the pre-amplification circuit is located directly in the probe body, for example, VZ-48 or VZ-52/1.

 (2) Locator for concealed wiring, e.g. LA-1010 or AST-1210.

 (3) Temperature meters, e.g. ТМ979Н thermometer.

 (4) Laboratory power supplies, e.g. AKIP B 5-71.

 (5) Device for parametric control of multilayer printed circuit boards RU 6187225 C1 published July 10, 2005

The closest device (prototype) to the claimed by me is the Device for parametric control of multilayer printed circuit boards RU 2256187 C1 published July 10, 2005.

 The device is intended for output quality control of multilayer printed circuit boards, and consists of N pairs of spring-loaded ones, to ensure high-quality contact of the probe heads, which are located on opposite sides of the tested printed circuit board, and are moved by coordinate multi-axis movement units, which are controlled by movement control units according to commands of the built-in microcomputer, according to the program, individual for each multilayer printed circuit board.

Both this device and the multifunctional diagnostic complex that I propose can be used to control the quality of multilayer printed circuit boards.

Disclosure of a utility model.

 The disadvantage (with reference to the course of the problem I am solving) of the above devices is that since the functions of the above devices are not integrated, using them separately is inconvenient.

 In addition, the use of devices (2), due to their size, low sensitivity and resolution, is difficult, and devices (4), due to the lack of a power amplifier function in it, is impossible in the proposed device, intended mainly for repair and diagnostics of modern electronic devices assembled on multilayer printed circuit boards, including those using microcircuits in BGA packages.

The disadvantage of the device (5) is that since this device

it is intended for output quality control of manufactured multilayer printed circuit boards; due to its design features, it is unsuitable for working with finished products assembled on such circuit boards, since the probe head in the above device consists of a pair of spring-loaded contacts and a video camera, which is necessary for accurate positioning of the probe head, and is intended only for contact measurement of the resistances of conductors, interlayer transitions, metallized holes, insulation of circuits and electrical connections neny between mounting pads on the outer layers of controlled multilayer printed circuit boards.

In this case, all further signal processing is performed by measuring and switching modules that are located outside of the probe heads. This device does not make any other measurements, either by contact or non-contact, therefore, the inventors position the device as a device for parametric control, and not as a multi-channel probe.

In addition, this device, due to its cost and dimensions, is difficult to access for small enterprises and individuals.

The objective of the utility model I am proposing is to integrate the functions of the above devices in one, in order to increase functionality and ease of use for the repair and diagnosis of various electronic and electrical circuits and systems, including modern ones assembled on multilayer printed circuit boards, and can be especially useful when manually tracing the conductors located on the inner layers of multilayer printed circuit boards and working with microcircuits in BGA packages. Also

the proposed device may be useful for work when absent

circuit diagram of the diagnosed device.

The technical result is achieved by the fact that in a single common probe housing, the design of which looks like a multi-color ballpoint pen, supplemented with output cables, are placed:

1. Probe-contact multimeter / oscilloscope.

2. Non-contact current sensor of inductive or magnetoresistive type with

appropriate circuit pre-amplification of the current signal.

3. A non-contact voltage sensor of electrometric or capacitive type with the corresponding circuit for preliminary amplification of this signal.

4. A temperature sensor such as a thermocouple or thermistor with an appropriate circuit for preliminary amplification of the thermocouple signal or thermistor.

As well as the mechanical and electronic switching device of the above channels are located in a single common housing of the measuring probe.

In addition, the complex includes a combined device that can be used as a source regulated in amplitude and frequency

voltage / current, and as an amplitude and phase adjustable power amplifier, the load of which can be the diagnosed circuit and / or component, and the sensor of the corresponding channel, in order to increase sensitivity, can be included in the positive feedback circuit, or in order to increase selectivity into the negative feedback circuit.

 It is also possible to turn on the built-in speaker for audio control of the output signal.

Thus, the device that I propose has 4 measurement channels, mentioned above, each of which can be used in 4 modes, namely:

A) The measurement mode of the diagnosed system powered by its own power source. B) The measurement mode of the diagnosed system powered by an adjustable power source included in the complex.

C) The measurement mode of the diagnosed system in which, in order to increase

sensitivity of the complex, the diagnosed circuit or component is connected to the output of an adjustable power supply / power amplifier, and the corresponding channel is included in the positive feedback circuit for current or voltage.

D) The measurement mode of the diagnosed system in which, in order to increase

selectivity of the complex, the diagnosed circuit or component is connected to the output of an adjustable power supply / power amplifier, and the corresponding channel is included in the negative current or voltage feedback circuit.

Also, the video monitoring system of the diagnostic location, available in the prototype, has been replaced by an audio monitoring device of the diagnosed circuit and / or component in my device.

Implementation of the utility model "Multifunctional diagnostic complex." Structurally, the device consists of A:

The probe, in the common housing of which there are sensors, pre-amplifiers of all channels with the corresponding system of mechanical and electronic switching of channels. Externally, the design of the probe resembles a multi-color ballpoint pen complemented by output cables.

 A mechanical channel switching system can also be similar to a multi-color ballpoint pen color switching system.

One possible implementation of the probe is shown in FIG. one.

The probe-contact of the multimeter / oscilloscope is advanced by pressing switch Ш, while the probe-contact is connected to the output bus using the contact group S1, the outputs of other channels are switched off.

The non-contact current measurement channel, intended mainly for tracing hidden conductors (tracks) with low impedance and working with microcircuits in BGA packages, is activated by pressing switch P2, while:

1) The magnetic core of the inductive magnetic field sensor is advanced mechanically connected to switch P2.

2) The circuit (shown in Fig. 1) switches to the cascode amplifier mode with a dynamic load of the inductive magnetic field sensor signal, namely: the preliminary amplification of the inductive magnetic field sensor signal is carried out by a low-noise transistor of the type KT 3102Zh switched on according to the circuit with a common emitter, whose collector load is a 6С51Н type nouvistor connected according to the scheme with a common grid (contact group S 2/2 mechanically connected with switch P2 is in the upper position) current source is compiled in a "current mirror" transistors VT2 and VT3 type KT361G, yield cascode amplifier S2 via contact group / 2 is connected to the output line, wherein the outputs of other channel is disabled. The non-contact voltage measurement channel, intended mainly for tracing hidden conductors (tracks) with high impedance, is switched on by pressing the PZ switch, while the circuit shown in Fig. 1, using the contact group S 3/1, goes into the mode of a sinusoidal oscillator operating at a frequency of the order of 50 megahertz collected on a 6С51Н nouvistor according to the classical three-point capacitive scheme (Kolpitz generator). The choice of a nouvistor is due to its significantly greater electrostatic resistance compared to semiconductor devices.

The parasitic capacitance of the conductor and / or component of the diagnosed device is the bottom, according to the scheme, lining Seq. Oscillating circuit L5 Seq., the upper lining Seq. located on the probe body. The varicap scheme is used for tuning

equivalent capacitance of the oscillating circuit to obtain stable generation. The input signal of the cascade on the transistor VT1 using the contact group S2.1

it is grounded and this cascade enters the mode of the cathode resistor of the 6C51H nuvistor. The output of the generator using the contact group S 3 is connected, for further processing, to the output bus, the outputs of other channels are disabled.

The temperature measurement channel is activated by pressing the switch P4 while:

1) A thermocouple type temperature sensor is pulled out, mechanically connected to switch P4.

 2) The circuit depicted in FIG. 1, which is a thermocouple signal amplifier, is made according to the standard scheme on a specialized operational amplifier like AD8551 and is connected to the output bus using contact group S4, while the outputs of other channels are switched off. and B:

Amplitude, frequency and phase adjustable combination device

power supply / power amplifier.

The operation of the combined device power supply / power amplifier in the power supply mode.

Consider the operation of a combined device on the example of a block diagram of the popular TL494 chip, widely used in switching power supplies (see figure 2).

The basis of the pulse-width-wave regulation node of this microcircuit is the DA2 comparator, to the inverting input of which, from the DA6 generator, whose frequency of operation is determined by the values of the resistor RT and the capacitor ST, a sawtooth signal is supplied, and to the non-inverting input which is connected to the DA3 operational amplifier (amplifier voltage error signal), operational amplifier DA4- (error amplifier for current limiting) and pin 3, at the same time, a signal is supplied which needs to be modulated.

 In power supply mode, voltage is applied to this input

UBX = kl * Uon.-k2 * UBbix. + K3 * lBbix. Where:

Uon. voltage reference that must be stabilized.

 11out. stabilizer output voltage

 1out. stabilizer output current

 kl, k2 k3 coefficients specific to each specific power supply circuit.

At the output of the comparator, we obtain rectangular pulses whose width

proportional to the level of the modulated signal, in this case UBX.

Then, from the output signal of the comparator, the auxiliary logic unit on the elements DDI, DD2, DD3, DD4, DD5, DD6 generates a paraphase signal for the half-bridge output stage operating in the key mode.

 In case of load of the output key stage to the isolation and matching transformer, the output voltage from this transformer is rectified and an LC filter is applied, which is switched between the output key stage and the load demodulates and filters the output current pulses.

Operation of the combined power supply / power amplifier device in the power amplifier mode.

 Option 1.

 The operation of the combined device is a power supply / power amplifier in the class D amplifier mode.

Class D - cascade operation mode in which active devices operate in key mode. The basis of this circuit is the master oscillator of a sawtooth or triangular circuit, the frequency of which is usually equal to tens or hundreds of kilohertz, a high-speed comparator and pulse shaper that controls the output transistors operating in the key mode. Demodulation of the amplified signal produces an LC filter which is switched between the output stage and the load.

Kotelnikov theorems: Any analog signal can be reconstructed with any accuracy from its discrete samples taken with a frequency f> 2fc, where fc is the maximum frequency to which the spectrum of a real signal is limited.

Thus, to obtain a bandwidth of the power amplifier equal to 10 kilohertz, the frequency of the master oscillator sawtooth or triangular should be at least 20 kilohertz.

Since the basis of the node of the pulse-width regulation of the amplifier is the DA3 comparator, the sawtooth signal is supplied to the inverting input of which from the DA6 generator, the signal that needs to be modulated is supplied to the other input, in our case, the voltage from the probe output is applied to this input.

If the instantaneous value of the input voltage exceeds the voltage at the generator output, the comparator sends a signal to open the upper arm, if not, to open the lower arm. If necessary, amplifiers DA3 and DA4 can be used to introduce negative or positive feedbacks on voltage or current. Then, from the output signal of the comparator, the auxiliary logic unit on the elements DDI, DD2, DD3, DD4, DD5, DD6 a paraphase signal is generated for the half-bridge output stage operating in the key mode. The pulse shaper amplifies these signals alternately opening the upper and lower arm transistors, and the LC filter between them demodulates and smooths the current supplied to the load. At the output of the amplifier, a copy of the output signal is amplified and demodulated, cleared of high-frequency noise.

 The disadvantages that prevent the widespread use of class D amplifiers are a rather high coefficient of non-linear distortion and higher requirements for the speed of components, but in our case these disadvantages are not so significant.

Option 2

 The operation of the combined device power supply / power amplifier in the class A amplifier mode.

The combined device consisting of a step-down mains transformer, a rectifier, a mains filter, a primary parametric stabilizer,

sequential compensation adjustable stabilizer based on the operational amplifier and mode switch.

In this circuit (shown in FIG. 3), the operational amplifier is actually turned on according to the non-inverting amplifier circuit, the output of which is connected to the base of a powerful

a transistor connected according to a circuit with a common emitter (current amplifier). The ratio of resistors in the feedback circuit of such an amplifier is determined by its gain, Ky = l + Rl R3, which determines how many times the output voltage will be higher than the input, that is, the voltage supplied to the non-inverting input of the operational amplifier. In the power supply (voltage stabilizer) mode, the reference voltage from the parametric stabilizer Rv D1 is applied to this input. In the power amplifier mode, this input switches to the output signal of the probe, and the diagnosed circuit or component is connected to the amplifier output.

 The variable resistance R2 standing in the negative feedback circuit and being a voltage regulator in the power supply mode, in the power amplifier mode serves as a gain regulator.

Option 3

 A combined device power supply / power amplifier in which the function of the power amplifier can be implemented on a microcircuit of a power amplifier, for example, such as TDA1557, which is structurally and schematically integrated with a power supply to implement the functions of the claimed utility model.

SOURCES

 Device for parametric control of multilayer printed circuit boards, RU 2256187 C1

Labutin, V.K. Class D. Amplifier. M. Gosenergoizdat. 1956

 Livshits, I. I. Transistor amplifiers in the mode D. L. Energy, 1973.

 Bohn, D. A. Pro Audio Reference, Rane Audio, 2012, Amplifer classes: Class D

 Bohn, D. A. Pro Audio Reference, Rane Audio, 2012, Amplifer classes: Class A

 Texas Instruments, Datasheet TL494.

 Philips, Datasheet TDA1557

Claims

FORMULA

1. A multifunctional diagnostic complex consisting of a multi-channel probe, a combined power supply unit / power amplifier, which can be used both as an adjustable power supply unit and as a power amplifier, and output circuits for connecting to a multimeter and an oscilloscope.

2. The device according to claim 1, characterized in that the multifunctional diagnostic complex includes 4 or more channel probes with corresponding sensors, signal pre-processing circuits, and a channel mechanical and electronic switching system.

3. The device according to claim 1, characterized in that the multifunctional diagnostic complex includes a combined power supply unit / power amplifier that can be used as a voltage / current source for voltage / current for the tested circuits, and in as a power amplifier adjustable in amplitude and phase, in order to organize a positive and

negative feedbacks on current and voltage to increase the sensitivity and selectivity of the complex.

4. The device according to claim 2, is characterized by the ability to optionally select the channel of the channel for contact measurement of the signal, that is, the probe-contact of the multimeter / oscilloscope.

5. The device according to claim 2 is characterized in that the contact measurement signal sensor, that is, the probe-contact of the multimeter / oscilloscope, as well as the mechanical and electronic switching device of the contact measurement signal channel are located in the common housing of the measuring probe.

6. The device according to claim 2 is characterized by the possibility of optional channel selection

non-contact current measurement in low impedance circuits.

7. The device according to claim 2, characterized in that the current sensor, a circuit for pre-amplification of the current signal, as well as a mechanical and electronic switching device for a non-contact current measurement channel, are located in a common probe housing.

8. The device according to claim 2, characterized in that the current sensor can be manufactured using both an inductor and based on semiconductor structures such as magnetoresistors, Hall sensors, etc.

9. The device according to claim 2, characterized in that the non-contact current measurement channel can be used for passive monitoring of current circuits.

10. The device according to claim 2, characterized in that the non-contact current measurement channel can be included in the positive or negative current feedback circuit.

11. The device according to p. 3, characterized in that the parameters of positive or negative current feedback, such as current strength, frequency, phase are adjustable.

12. The device according to claim 2, characterized by the optional inclusion of a non-contact voltage measurement channel in high impedance circuits.

13. The device according to claim 2, characterized in that the non-contact voltage sensor, the signal pre-amplification circuit, as well as the mechanical and electronic switching device for the non-contact voltage measurement channel are located in the common housing of the measuring probe.

14. The device according to claim 2, characterized in that the non-contact voltage sensor can be either capacitive or electrometric type.

15. The device according to claim 2, characterized in that the non-contact voltage measurement channel can be used for passive monitoring of the voltage potential

high impedance circuits.

16. The device according to claim 2, characterized in that the non-contact voltage measurement channel can be included in the positive or negative voltage feedback circuit.

17. The device according to claim 3, characterized by the ability to adjust the parameters of positive or negative feedback on voltage, such as amplitude, frequency and phase.

18. The device according to claim 2, characterized by the optional inclusion of a temperature measurement channel.

19. The device according to claim 2, characterized in that the temperature sensor, a signal pre-amplification circuit, as well as a mechanical and electronic switching device for the temperature measuring channel, are located in a common housing of the measuring probe.

20. The device according to claim 2 is characterized in that both a thermocouple and temperature sensors based on

 semiconductor structures.

21. The device according to p. 3, characterized in that it is possible to turn on the built-in speaker for audio control of the output signal.