Integrated circuit for conditioning and conversion of bi-directional discrete and analog signals

FIELD OF INVENTION

The present invention relates to the field of programmable input and output interfaces and in particular to an integrated circuit that can be programmed to accommodate various input/output signals with different characteristics at the same time and through the same interface.

BACKGROUND OF INVENTION

For any computer-controlled electrical system, the handling of input and output between components of the system is an important aspect of the system. An interface between components of a system can convert or condition an output signal from one component to become a compatible input signal in another component. This conversion or conditioning must be performed while maintaining the signal's integrity and accuracy.

Often, an input/output interface will have to coordinate input and output signals with extremely varied signal characteristics. For example, one component can have analog signals that need to be converted into digital signals in order to be analyzed by another component. In another instance, typical for aircraft, analog signals from one component can have a voltage range as great as (−15 to +28) volts while another component in the system has a voltage range of +/−5 millivolts. Other situations entail having components that utilize both differential and single-ended signals that have to be input to another component.

Given the wide variety of signal characteristics that can exist within a given system, input/output interface designs are typically developed to apply to a specific system. In particular, for systems on an aircraft, sensors on the aircraft can produce widely different output signals that have to be converted and conditioned in order to be processed by the aircraft computers. Typically, a different input/output interface is developed for every sensor to produce a digital stream of data readable by the aircraft computers.

Redesigning the input/output interface every time a new sensor is used wastes valuable time and money, as the designer must gain expertise with these sensors before designing the new interface. As such, there exists a need for a compact device that can be easily incorporated into a component system and programmable to handle a multitude of signals of varied characteristics to create a single standard interface between components of that system.

SUMMARY OF THE INVENTION

This invention comprises a configurable integrated circuit (IC) which is advantageously a single miniature chip to coordinate input and output (I/O) signals. The chip performs signal conditioning, analog-to-digital and digital-to-analog conversion. Both single-ended signals and differential signals can be handled at each channel of the chip. In addition, each channel is configurable to accept input signals or generate output signals. This invention enables the reuse of I/O hardware across multiple applications and reduces chip count, board space and connections and thus increases design reliability.

In one illustrative embodiment an input/output interface within a computer controlled electrical system comprises a plurality of signal conditioning cells to provide a physical interface for electrical signals in the system where each of the plurality of signal conditioning cells is capable of handling signals with different characteristics. A signal conversion cell connected to the signal conditioning cells is capable of converting each of the electrical signals on the plurality of channels to become a digital data value for the computer. The plurality of signals includes discrete signals, analog signals, differential signals, or single-ended signals.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1

depicts a generic block diagram of an aircraft computer interfacing with various sensors and controlled devices using an integrated circuit in accordance with an illustrative embodiment of our invention.

FIG. 2

is a circuit diagram of a single conditioning cell in accordance with one embodiment of our invention.

FIG. 3

is a circuit diagram of a single conversion cell in accordance with one embodiment of our invention.

DESCRIPTION OF THE INVENTION

FIG. 1

depicts a typical aircraft system in which our invention may be employed. Sensors

101

on an aircraft produce continuously varying analog and or on-off discrete signals that need to be processed by the aircraft computer

103

. Each sensor

101

can produce a signal that has different characteristics than other sensors because of the different types of sensors that are necessary to be on an aircraft. An integrated circuit

105

in accordance with our invention is interposed between the sensors

101

and the computer

103

. The integrated circuit

105

can be installed in either the same line replaceable unit (LRU) as the aircraft computer or in a separate ‘black box’. Each sensor

101

will transmit its signals to the integrated circuit

105

that conditions and converts the signals into a digital form that can be read by the aircraft computer

103

. In turn, the aircraft computer

103

can send digital signals back to the integrated circuit

105

. These signals will also be conditioned by the integrated circuit

105

and then transmitted to other controlled devices

107

on the aircraft.

FIG. 1

also depicts the layout of one illustrative embodiment of the integrated circuit

105

of our invention. The physical implementation of the integrated circuit

105

is advantageously embodied as a single semiconductor chip, but any other similar implementation can be used.

The integrated circuit

105

includes a number of signal conditioning cells (

111

A to

111

N) that each provide pairs of physical leads (

121

A to

121

N) and (

122

A to

122

N) to physically connect the integrated circuit with the various types of signals within the component system. Each signal conditioning cell

111

can be configured by the aircraft computer

103

to condition a number of different signal types as described below. The signal conditioning cells (

111

) condition each input signal by buffering the input signal characteristics into standard signal characteristics, for example −10 volt to +10 volt, that can be converted by a shared analog to digital converter

303

, shown in FIG.

3

. The signal conditioning cells

111

condition each output signal by buffering a standard signal, for example −10 volt to +10 volt, that is provided by a shared digital to analog converter

325

shown in

FIG. 3

, into output signals with various signal characteristics. The signal conditioning cells

111

interface with a signal conversion cell

113

via an output multiplexor, for example a shared output analog signal bus

115

and an input multiplexor, for example a shared input analog signal bus

117

. Signal conversion cell

113

includes registers that store digital values of the input and output signals and also configuration information for each of the signal conditioning cells

111

. Signal conversion cell

113

also includes a sequencer and control module

343

, shown in

FIG. 3

, which organizes the interaction among the various internal cells of the integrated circuit

105

.

Advantageously, an integrated circuit in accordance with our invention is able to accommodate both input signals and output signals.

FIG. 2

depicts a signal conditioning cell circuit that allows each channel to be programmed to accept input signals or produce output signals without affecting the signal. Physical leads

121

and

122

are connected to the inputs of an input amplifier

205

and connected through transmission gates to both a current driver

225

and a voltage driver

223

. In one embodiment of the invention, the input amplifier

205

is an operational amplifier and the physical lead

121

is connected to its non-inverting (+) input and physical lead

122

is connected to its inverting (−) input. Sequencer and control module

343

controls the on-off setting of current driver transmission gate

234

based on values that the aircraft computer

103

has stored in the configuration register file

341

, shown in FIG.

3

. Sequencer and control module

343

controls the on-off setting of voltage driver transmission gate

235

based on values that the aircraft computer

103

has stored in the configuration register file

341

. Voltage driver

223

can also be programmed to function as a common mode voltage reference for a adjacent signal conditioning cell

111

by supplying an output, for example to connection point

123

A. When a signal conditioning cell is configured to receive an input, both the current driver transmission gate

234

and the voltage driver transmission gate

235

are set into high impedance states by the sequencer and control module

343

, shown in FIG.

3

.

When the signal on the signal-conditioning cell is to be output, the input operational amplifier

205

is still activated and will have no effect on the output signal. Having the input still activated while producing an output signal allows the invented system to be self-testing. Since the input is always connected to the final output, the input can be checked at any time to be certain that the output is functioning properly.

Referring again to

FIG. 2

, the physical leads

121

and

122

interfacing with the signal conditioning cell

111

of integrated circuit

105

are paired up to create one signal channel. Having two leads per signal channel is necessary in order to be able to accommodate both differential signals and single-ended signals. In addition to providing the physical leads, the signal conditioning cell

105

implements circuitry to be able to handle a number of different signal types. Input amplifier

205

buffers input voltage signals. Load resistor

201

is connected across physical leads

121

and

122

via transmission gates

232

and

233

to convert input current signals into a voltage input for input amplifier

205

. In one embodiment of our invention, transmission gates

232

and

233

are field effect transistors (FET) with “on” impedance of 190 ohms and load resistor

201

has a value of 620 ohms. Sequencer and control module

343

controls the on-off setting of transmission gates

232

and

232

based on values that the aircraft computer

103

has stored in the configuration register file

341

, shown in FIG.

3

.

When the signal conditioning cell

105

is producing an output signal on physical leads

121

and

122

, this output signal is wrapped back for built-in test purposes and monitored as an additional input signal. All input signals are treated as differential signal inputs. In instances where a single-ended signal is utilized, for example by an aircraft sensor, each signal conditioning cell

105

has a transmission gate

231

that allows one of the physical leads to be connected to a common ground point and an input

123

, also shown in

FIG. 1

, that allows another signal conditioning cell to provide a common mode voltage reference. By having two leads for the differential signal, the differential signal keeps its integrity and the single-ended signal has a reference to its local ground. Discrete signals are treated as single-ended analog signals thereby adding the benefits of programmable hysteresis and programmable debounce.

Referring to

FIG. 1

, signal conversion cell

113

will either receive the input signals from or transmit an output signal to each signal-conditioning cell (

111

A to

111

N). Referring back to

FIG. 3

, for input signals from the signal selection module, The input operational amplifier

205

scales the signal to the full range supported by an analog to digital converter

303

, shown in

FIG. 3

, while maintaining signal integrity and accuracy. A programmable gain module

207

is connected across the non-inverting input of input operational amplifier

205

. In one embodiment, the programmable gain module

207

is implemented as a system of resistors in parallel with transmission gates to switch them in or out of the circuit and vary the feedback resistance to determine the total gain according to the following formula:

V

OUT

=

R

Feedback

R

Input

*

V

Input

Eq

.

⁢

(

1

)

The scaling step of the input operational amplifier

205

produces the maximum resolution for a number of signal ranges using a single range converter. For example, the scaling range for the signals should be able to handle ranges, typically found in aircraft, as great as −15V to 28V signals.

The signal can also be filtered through optional programmable low-pass filter

209

after passing the input operational amplifier

205

. The filtering of the signal is used mainly as an anti-aliasing low pass filter that can be implemented by a switched capacitor network.

Advantageously, our invention includes an input signal multiplexor. For example, after the signal optionally passes through the filter

209

, it is routed into a multiplex transmission gate

241

, which selectively determines when the signal is connected to the input analog signal bus

117

at connection point

127

, as shown in FIG.

1

.

For output signals, either the current driver

225

or the voltage driver

223

can be enabled. The voltage driver

223

amplifies the voltage at a variable gain similar to the input operational amplifier

205

. The current driver

225

has a set number of currents that can be selected when programmed. Output signals from both the current drivers and voltage drivers are presumed to be single-ended and reference to a local ground is provided as a signal return. An embodiment of the present invention to produce a differential signal uses two separate channels whereby one channel carries the true signal and the other carries the negative signal.

FIG. 3

depicts the several components of the signal-conversion cell

113

. Before transmitting the input signal to the analog to digital converter module

303

, the signal conversion cell uses an input signal multiplexor, for example an input analog signal bus

117

, shown in

FIG. 1

, and a sample and hold module

301

to prepare the various analog input signals to be converted by the converter module

303

. Input analog signal bus

117

is connected to each signal-conditioning cell

111

of the integrated circuit

105

.

In one embodiment of the input signal multiplexor of our invention, the sequencer and control module

343

routes analog data from a selected signal-conditioning cell

111

by activating the multiplex transmission gate

241

, shown in

FIG. 2

, in that particular cell. The selected signal is routed from connection point

127

, via the input analog signal bus

117

and connection point

137

to the input of a sample and hold module

301

. Sample and hold module

301

will sample a given signal and will hold the signal's analog value to ensure that a stable unchanging signal is available to an analog to digital converter

303

. The analog to digital converter

303

must have a stable analog input signal to ensure that proper conversion occurs. Analog to digital converters

303

convert the various analog signals to digital values. In one embodiment, the analog to digital converter has twelve bit precision.

A digital decoder

305

is used to map the various digital signals, after conversion to digital format, to input register file

307

at an address corresponding to the appropriate signal conditioning cell

111

. When the data to be latched is placed on a bus that feeds to the register file, the address of the selected register is fed into the decoder by the sequencer and controller

343

. The decoder sends a signal to the selected register's enable, and the data is latched into that register.

The digital signals are first transmitted to a digital decoder

323

that parses out the digital signals from the input register file

321

. The digital decoder

323

ensures that only one output value at a time, stored in the registers is routed to the digital to analog converter

325

. When the address of the selected register is fed into the decoder

323

, the selected signal input is routed to the converter

325

.

After digital to analog converter

325

converts the signal from a digital format to an analog format, the signal is routed via connection point

135

to an output signal multiplexor, for example the ,output analog signal bus, shown in

FIG. 1

, and to each signal conditioning cell at connection point

125

. The sequencer and control module

343

then asserts a digital signal to the sample and hold module

221

of the selected signal conditioning cell (

111

A to

111

N) that will then hold the analog signal value present on the output analog signal bus.

Advantageously, the combination of transmission gates

241

, an analog input analog signal bus

117

, a sample and hold module

301

and a digital decoder

305

for the input path and the corresponding combination of digital decoder

323

, output analog signal bus

115

, and sample and hold modules

221

for the output path allow a reduction in the amount of analog to digital converters

303

and digital to analog converters

325

utilized, which saves space in the compact general purpose interface integrated circuit

105

. Instead of implementing a separate converter for each physical input/output channel, the signals are multiplexed and controlled to allow one converter to be used for multiple channels.

From the internal registers of the converters, the data is placed or taken from the integrated circuit's register files

307

and

321

. The register files

307

represent the interface to the chip from the computer

103

. Three groups of register files are needed for input data, output data and configuration data. The number of registers per file depends on the number of signals the chip is designed to handle. The size of each register depends on the accuracy of the conversion logic. For twelve-bit precision, a register with twelve-bit memory capacity is needed.

Reading the input register file can access values associated with samples of input signals. The aircraft computer will be able to access the information from the sensors

101

by accessing these input registers. To output information through the invented system, the aircraft computer

103

can write the data to the output register file.

Advantageously, the double-buffering system described above using aircraft computer internal system files and the interface register files of the present invention is useful for a synchronous access to the chip to ensure stability of the sampled values before processing them or being read out of the chip. A further embodiment of our invention allows the aircraft computer to also directly access the analog to digital converter's registers and the digital to analog converter's registers.

The configuration register file

341

stores the gain and type of conditioning for each signal. Using the values stored in the configuration file register, the sequencer and control module

343

can organize the interaction among the internal modules and handle the mapping of the internal registers of the converters. The sequencer and control module

343

can also reconfigure the modules and control access to input register file

321

and output register file

307

. The sequencer and control module

343

ensures the correct order of internal operations and the synchronization of the input and output data streams.

The present invention is not to be considered limited in scope by the preferred embodiments described in the specification. Additional advantages and modifications, which will readily occur to those skilled in the art from consideration of the specification and practice of the invention, are intended to be within the scope and spirit of the following claims.