Abstract:
A control apparatus for controlling the temperature of an environmental chamber within which a device is tested for thermal characteristics employs a pair of control elements connected in cascade. The first element produces a required air temperature in response to a desired temperature and to the temperature of the device; the second produces a temperature set point in response to the required and actual air temperatures. Possible stress on the device is avoided by limiting the range of required air temperature. Response is accelerated by a pass-through circuit, parallel to the first element, which responds to a change in the desired temperature by adding to the required air temperature of value proportional to the change.

Description:
BACKGROUND OF THE INVENTION 
     The invention is in the field of environmental control, and particularly concerns an apparatus and a method for accelerating the reaction of an environmental test system to the environmental response of a device under test in the system. 
     In the process control field, a system for performing an industrial process (the controlled system) gives forth its desired product in response to automatic means (the control system) which dynamically correct process parameter values of the controlled system in a manner which makes the result of the process fall within a predetermined range of values. 
     Control systems employ a technique called &#34;cascading&#34;. In this regard, a control system can include more than one compensating unit which responds to the current values of a first set of process parameters by producing an operating signal. In a cascaded control system, the operating point signal of one control unit is provided as one input to another compensating unit. 
     Conventionally, cascade control has been applied to control relatively &#34;slow&#34; primary physical processes through secondary control of &#34;faster&#34; processes. For example, in a heat exchanger system, steam is introduced into a heat-exchanger to provide a source of thermal energy for heating a reagent. The slow process of heating the reagent is controlled in a primary unit by manipulation of the heat exchange process in response to the present heat of the reagent and the desired heat. The primary unit produces a thermal change value. The value of the available heat parameter (steam flow) is controlled in a secondary compensation unit having a fast reaction to the thermal change value and steam heat. The secondary unit produces a signal which quickly controls the flow of steam. 
     A well-known industrial process is embodied in an environmental chamber which is used to test a device (&#34;device under test&#34; or &#34;DUT&#34;). The industrial process to be controlled is one or more environmental effects produced by the chamber. For example, the thermal response of a device is evaluated in an environmental chamber having means for establishing the temperature of its interior and for changing that temperature at a selected rate to another temperature. The temperature of the DUT changes in response to the change in environmental chamber temperature at a rate determined by physical characteristics of the device. The temperature responses of the device and the environmental chamber are both relatively slow industrial processes. Furthermore, the thermal characteristics of the device will vary under varying test conditions of pressure, humidity, and temperature. Last, control of the chamber temperature as a secondary variable in a cascade control system can lead to high, and possibly fatal, thermal stress on the device under test. 
     SUMMARY OF THE INVENTION 
     The invention employs accelerating control of the environmental response of a test chamber by reacting to the difference between the temperature (PV 1 ) of a device under test to a prescribed setpoint temperature (SP 1 ), enabling the test chamber to respond quickly to changes in SP 1  without subjecting the device to unacceptable levels of thermal stress. 
     The invention achieves this important objective by cascading a primary controller operating on the difference between PV 1  and SP 1  with a secondary controller operating on the difference between the output of the primary controller and the temperature of the environmental chamber in which the device under test is located. In this manner, the thermal response of the device under test to changes in chamber temperature as indicated by the primary controller can be used to control the chamber temperature through the secondary controller. 
     This basic complement of components permits cascade control of two relatively &#34;slow&#34; thermal processes and, therefore, achieves the objective of controlling environmental chamber temperature in response to the varying thermal characteristics of a device under test and the second goal of avoiding unacceptable thermal stress of the device. 
     These and other objections and advantages of this invention will be evident when the following disclosure is read with reference to the below-described drawings. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is an illustration of the environmental response control apparatus of the invention in combination with an environmental chamber containing a device under test. 
     FIG. 2 is a more detailed illustration of the apparatus of the invention. 
     FIG. 3 illustrates a programmable circuit for executing the environmental response control procedure implemented by the invention. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     There is great difficulty in characterizing the response of an environmental chamber prior to its use in testing devices. Prequalification of such a chamber involves extensive and lengthy procedures to accurately establish its thermal, pressure, and humidity responses of to setpoint values. In this regard, setpoint values are electrical signal representations of the profiles of desired environmental conditions within the chamber. For example, a thermal setpoint signal can represent a chamber temperature profile beginning at an initial temperature, changing at a first rate in degrees per minute to a second temperature, staying at the second temperature for a period of time and then changing to a third temperature at a second rate. 
     An environmental chamber exhibits a definite response to a setpoint signal; characterization or prequalification of the chamber illustrates the chamber&#39;s response. Such characterization is required in order to account for the thermal response of the device under test. The setpoint profile represents the desired temperature profile of the device under test; however, the complex thermal response of the device under test and the environmental chamber must be accounted for. The characterization step determines this complex response with the device in the chamber, and provides the basis for changing the setpoint signal profile to one which, when used to control the temperature in the chamber, will cause the device under test to exhibit the desired profile. 
     The invention eliminates the requirement for characterization by provision of a cascaded primary and secondary controller in which the primary controller generates an operating point signal in response to the setpoint profile and the temperature of the device under test. This first operating point value is then provided as a setpoint temperature value to a secondary controller which compares it to the actual temperature in the environmental chamber and generates a second operating point signal provided to the heating and cooling controls of the environmental chamber. 
     FIG. 1 illustrates the invention in its intended environment of application. The invention is intended to be used with an environmental chamber 10. The chamber 10 may be of the conventional type, and includes a system 12 for heating and cooling the air temperature within a test space 13. The test space 13 contains a device 14, referred to as the device under test, whose response to a dynamic thermal environment is to be evaluated. In the invention, the response of the device under test is indicated directly by its temperature. This response is sensed by the temperature sensor 16, which is attached to, or embedded in, the device, and which can comprise a conventional thermocouple. The sensor 16 produces an electrical signal having a magnitude proportional to the temperature of the device 14. The signal representing the temperature of the device under test is provided on a signal line 17. The parameter directly affecting the temperature of the device under test is the temperature of the air provided by the chamber heating and cooling system 12. The temperature of the air is sensed by a conventional temperature sensor 18 which provides an electrical signal on line 19, the signal having a magnitude proportional to the temperature of the air. 
     THE INVENTION 
     The control apparatus of the invention is indicated by reference numeral 25. The control apparatus includes a setpoint generator 26 which generates a setpoint signal corresponding to a desired thermal profile for the device under test. The profile is indicated by the waveform 27 which presents a thermal profile in units of degrees centigrade per time. The setpoint generator 26 produces an electrical signal corresponding to the thermal profile 27. The electrical signal is referred to as a setpoint signal and is provided as a desired part temperature signal on signal 28. 
     The control apparatus includes a primary controller 30 which responds to the setpoint temperature signal on signal line 28 and the signal representing the actual temperature of the device 14, provided on signal line 17, to produce a first operating point signal corresponding to the value of the air temperature in the test space 13 required to produce the desired part temperature indicated by the setpoint signal. The first operating point signal is provided on signal line 32. 
     A secondary controller 34 receives the first operating point signal and the signal representing the actual temperature of the air in the test space 13. These two signals are combined by the secondary controller to produce either a cooling signal on signal line 36 or a heating signal on signal line 38. If the temperature requires cooling, the cooling signal on signal line 36 represents the amount of cooling necessary to achieve the required air temperature; similarly, if heating is required, the magnitude of the signal on signal line 38 corresponds to the amount of heating necessary to achieve the required temperature. 
     The control apparatus 25 of FIG. 1 can be implemented either as a set of discrete hardware components, or as a process executing in real time in a programmed processor. In either case, the inventor contemplates that conversion of signals rendered in digital form on signal lines 36 and 38 will be required. Thus, digital to analog converters 37 and 39 are provided to convert the signals produced by the secondary control 34. Analog signals would, therefore, be provided on signal lines 41 and 43 to operate the heating and cooling system 12. 
     The invention is illustrated, in its hardware aspect, by conventional control system representation in FIG. 2. Parts which FIG. 2 has in common with FIG. 1 are illustrated by identical reference numerals. In FIG. 2, the setpoint generator 26 can comprise any of a variety of available waveform generators. The setpoint generator is connected by signal line 28 to the primary controller 30. As FIG. 2 illustrates, the primary controller 30 includes a proportional, integrating (PI) control element 54 which receives the setpoint signal (SP 1 ) on signal line 28a and the device temperature signal PV 1  on signal line 17. The control element 54 operates to develop a deviation signal e 1  by subtracting the device temperature signal from the setpoint signal, and operates conventionally to produce an operating point set signal (OP 1a ) on signal line 55. The primary controller 30 further includes a setpoint pass-through circuit 56 which receives the setpoint signal SP 1  on signal line 28b and produces a set point proportional signal (k 0  SP 1 ) on signal line 57. Signal lines 55 and 57 feed a conventional summing junction element 58 which adds the magnitude of the operating point set and proportional signals to produce a first operating point signal OP 1b  on signal line 60. 
     The primary controller 30 also includes a boost limit circuit 52 which receives the first operating point signal OP 1b  on signal line 60. The boost limit circuit 52 operates conventionally to limit the absolute value of the negative and positive magnitude of the first operating point signal to a value H TB . In this regard, when the magnitude of the first operating point signal at the summing point junction 58 exceeds the absolute value of H TB , the signal output by the boost limit circuit has its magnitude limited to the absolute value of H TB . Between the positive and negative magnitude limits, boost limit circuit 52 provides the first operating point signal unchanged on signal line 32. 
     The first operating point signal processed by the boost limit circuit 52 is provided as a second setpoint signal (SP 2 ) to the secondary controller 34. Preferrably, the secondary controller 34 is a proportional, integrating-differentiating control unit which generates a second operating point signal (OP 2 ) in response to a deviation signal having a value equal to the difference between the chamber temperature signal PV 2  on signal line 19 and the second setpoint signal SP 2  on signal line 32. 
     For an understanding of the functions of the elements of FIG. 2 in controlling the operation of the control apparatus 10 of FIG. 1, the following theoretical description is provided. The primary controller 30 of the apparatus of the invention includes a proportional-integral (PI) control unit 54 operating on the deviation value e 1  resulting from comparison of PV 1  with SP 1 . It provides an operating point set signal OP 1a  according to equation (1), wherein: 
     
         OP.sub.1a =k.sub.1 e.sub.1 +(k.sub.1 /t.sub.i1)∫e.sub.1 dt+C.sub.1 (1) 
    
     In equation 1, the first term k 1  e 1 , represents a proportionality term. The second term includes an integral term with an appended constant C 1 . In the second term, the parameter t i1  represents a time interval over which the deviation value is integrated, and the constant C 1  is the usual constant which attends integration. 
     Under conventional cascade control, one would expect the signal OP 1a  to be applied directly to the secondary controller as SP 2 . However, in the control strategy of this invention, two significant modifications to this convention are made. 
     The first modification to convention is the pass-through of the first setpoint signal SP 1  by way of 28b, 56, and 57. The pass-through is summed with the output of the control unit 54, OP 1A  in the summing junction 58 according to equation (2), wherein: 
     
         OP.sub.1b =OP.sub.1a +k.sub.0 SP.sub.1                     (2) 
    
     In equation (2), the value k 0  is a constant; k o  SP 1  is the signal value generated by the pass-through circuit. At equilibrium, that is, when PV 1  =SP 1 , and SP 1  is unchanging, the first setpoint signal OP 1b  is a constant represented by C 0  in equation (3), wherein: 
     
         OP.sub.1b =C.sub.1 +k.sub.0 SP.sub.1 =C.sub.0              (3) 
    
     Preferrably, the control tuning constants for the primary controller&#39;s control unit 54 are established such that the proportional gain value, k 1 , is low and the integral time constant, t i , is short. Thus, when there is a change in the setpoint signal (δSP 1 ) the instantaneous response to the change can be approximated by equation (4), wherein: 
     
         OP.sub.1b =C.sub.0 +k.sub.0 (δSP.sub.1)              (4) 
    
     Thus, the input SP 2  to the secondary controller is, in effect, directly proportional to the setpoint for the device under test (SP 1 ). This value is modified, as described by equations (2)-(4) by the action of the primary controller 30. 
     The second major modification to convention is found in the action of the boost limit circuit 52. For purposes of this description, the action of the primary controller 30 on the secondary controller setpoint SP 2  is referred to as the &#34;boost&#34; level. The boost value has the effect of enhancing the chamber temperature response to the deviation el between the new setpoint (SP 1 ) and the device-under-test temperature (PV 1 ). Critical to the operation of the invention is the containment of the boost value range within prescribed limits. Without such limits, the temperature of the chamber could be driven to a level that might subject the device under test to excessive levels of thermal stress, or to thermal overshoot or undershoot during system stabilization. Relatedly, when the action of the primary controller causes the value of OP 1b  to exceed a boost limit, the value of SP 2  is constrained according to equations (5) and (6), wherein: 
     
         IF OP.sub.1b &gt;SP.sub.1 +H.sub.TB, THEN SP.sub.2 =SP.sub.1 +H.sub.TB (5) 
    
     
         IF OP.sub.1b &lt;SP.sub.1 -H.sub.TC, THEN SP.sub.2 =SP.sub.1 -H.sub.TC (6) 
    
     
         Otherwise, SP2=OP.sub.1b                                   (7) 
    
     Where H TB  represents a maximum allowable increase in chamber temperature, and H TC  represents a maximum allowable decrease in chamber temperature. 
     The method of the invention is practiced in a programmable circuit illustrated in FIG. 3. The programmable circuit is indicated by reference numeral 70 in FIG. 3 and can include, for example, a conventional available microprocessor system with CPU, memory, and associated I/O components. The programmable circuit 70 receives the PV1 and PV2 signals from the chamber 10. The signals can be provided in continuous form from the chamber 10 and converted in the circuit 70 by appropriate conventional procedures. Alternatively, the signals can be provided in digital form by the chamber 10 from appropriate conventionally-available sensors. The OP2 signal is provided by the circuit 70 to the chamber 10 in appropriate continuous or digital form. 
     The programmable circuit 70 includes three program modules. The first is a programmer module 70a, which acts as the primary signal interface between the programmable circuits 70 and the chamber 10. This module also provides intracircuit interface between a primary controller module 70b and secondary controller module 70c. The programmer module 70a also provides outputs appropriate to drive a visual display 72 for displaying the signals SP 1 , SP 2 , and OP 2 . 
     The modules of the programmable circuits 70 are represented in appended Tables I-III. The modules are given in conventional pseudocode format, it being asserted that the reasonably skilled circuit programmer will be able to derive product-specific, assembly-level implementations from these tables without undue experimentation. 
     Table I defines the essential data objects upon which the modules 70a-70c operate in executing the method of the invention. In this regard, lines 0101-0112 define specific data objects input to, and output from, the programmable circuits 70, and also signals generated internally by the modules 70b and 70c. 
     The procedure steps executed by the primary controller are steps 0200-0217 in Table I. In the procedure executed by the primary controller 70b, all registers are initially reset and normal operation is begun by reading the SP 1  signal from the programmer module 70a. The actual device temperature PV 1  is also obtained from the programmer module 70a and stored. Next, in step 0204, the primary controller calculates the deviation signal e 1 . The deviation signal is first integrated in step 0205 and added to the value stored in an offset register CF. In step 0206, an effective setpoint value is calculated by adding the contents of the CF register to the current value of SP 1 . In step 0206, the constant k 1  is equal to 1.0. Next, in step 0207, a second deviation signal is calculated by the primary controller by subtracting the actual device temperature from the effective set point value. The second deviation value is multiplied by the proportional gain term G 1  of the primary controller and is stored as a signal value OUTPUT 1. Steps 0209-0210 perform boost limitation by comparison against the values of H.sub. TB and H TC . The setpoint for the secondary controller is obtained in steps 0211-0213, which imposes a second boost limitation by, first, adding SP 1  to the OUTPUT 1 value obtained in steps 0209-0210, and flagging the resulting value as SP 2 . The value for SP 2  is constrained to lie in the range [MAXTEMP, MINTEMP]. The constrained value of SP 2  is provided to the secondary controller as its setpoint in step 0214, and the primary controller procedure is looped through step 0215. 
     Table II gives the pseudocode description of the secondary controller, which is initialized in steps 0300 and 0310. The value SP 2  is read into the procedure in step 0311, and the chamber temperature PV 2  is obtained in steps 0312. The second deviation signal is produced in step 0313 by subtracting PV 2  from SP 2 . In step 0314, a conventional PID (proportional-integrating-differentiating) control equation is applied to the second deviation signal and stored as OP 2 . In steps 0315, the second operating point signal OP 2  is provided to the chamber by way of the programmer module. The secondary controller procedure is looped through step 0316. 
     As the annotation preceding the programmer module of Table III illustrates, the programmer, in addition to serving as the primary external interface, can also provide message transfer service from the primary to secondary controller. Table III illustrates the programmer in the latter capacity. 
     The programmer module, illustrated in Table III, initializes in steps 0400 and 0401 and provides the setpoint SP 1  to the primary controller in step 0402. The programmer module then provides a signal to the display 72 for visual output of the SP 1  value sent to the primary controller. Next, the second setpoint SP 2  is obtained from the primary controller and sent to the secondary controller in steps 0404 and 0405. Then SP 2  is displayed in step 0406. The output of the secondary controller, the second operating point signal, OP 2  is provided from the secondary controller, to the chamber, and displayed in steps 0407-0409. The programmer module procedure loops through step 0410. 
     
                       TABLE I______________________________________DEFINITIONS AND PRIMARY CONTROLLER______________________________________0100 Definitions:0101 SP1 = System Setpoint (from programmer)0102 PV1 = Device Temperature0103 G1 = Proportional Gain of Primary Controller0104 SP2 = Secondary Controller Setpoint (from primarycontroller)0105 PV2 = Chamber Air Temperature0106 H.sub.TB = Heat Thermo Boost (the maximum allowablechamber temperature above the setpoint)0107 H.sub.TC = Cool Thermo Boost (the most negatie temperaturedifferential between the chamber temperature andthe setpoint)0108 MAXTEMP = Maximum Allowable Temperature for theChamber Setpoint0109 MINTEMP = Lowest Allowable Temperature for theChamber Setpoint0110 DEV1 = Deviation between SP1 and PU10111 DEV2 = Deviation between SP2 and PU20112 OP2 = Operating Point for Chamber0200 Reset All Registers0201 Start Normal Operation:0202 Read Desired Setpoint (SP1) from Programmer andStore in Memory as SP10203 Read Actual Device Temperature (PV1) and Storein Memory as PV10204 Subtract PV1 from SP1 and Store as DEV10205 Integrate DEV1 as a Function of Time and Add itsValue to the Value Stored in Offset Register(CF)0206 Add SP1 to CF and Store as ESP1 (effectivesetpoint #1)0207 Subtract PV1 from ESP1 and Store as DEV20208 Multiply DEV2 by the Proportional Gain Term G1and Store as Output 10209 If Output 1 is Positive then the System NeedsHeating and the Following Occurs:If the magnitude of output1 is greater thanthe magnitude of H.sub.TB, then set themagnitude of output1 equal to the magnitudeof H.sub.TB and store as output1.0210 If Output1 is Negative, then the system needscooling and the following occurs:If the magnitude of output1 is greaterthan the magnitude of H.sub.TC, then set themagnitude of output1 equal to themagnitude of H.sub.TC and store as output1.0211 Add SP1 to output1 and store as SP20212 If SP2 is greater than MAXTEMP, then set SP2equal to MAXTEMP and store as SP20213 If SP2 is less than MINTEMP, then set SP2 equalto MINTEMP and store as SP2.0214 Send SP2 to secondary controller as its setpoint0215 Jump back to &#34;Start Normal Operation 0201&#34; andrepeat endlessly______________________________________ 
    
     
                       TABLE II______________________________________SECONDARY CONTROLLER______________________________________0300    Reset all registers0310    Start normal operation0311    Read SP2 from programmer and store in memory0312    Read chamber temperature (PV2) and store in   memory0313    Subtract PV2 from SP2 and store as DEV20314    Apply PID control equation to DEV2 and store   result as OP20315    Send OP2 to chamber0316    Jump back to start normal operation 0310 and   repeat endlessly______________________________________ 
    
     In the system, the output of the primary controller is the setpoint for the secondary controller (the chamber air temperature controller). It can be connected directly or provided via the programmer, which serves as a communications device between the primary and secondary controllers. This is in addition to the normal programmer function of generating a setpoint for the two channels. 
     
                       TABLE III______________________________________PROGRAMMER______________________________________0400    Reset all registers on startup0401    Normal operation:0402    Send the setpoint to the primary controller as   SP10403    Display SP10404    Read the output of the primary controller as SP2   and store in memory0405    Send SP2 to secondary controller0406    Display SP20407    Jump back to &#34;normal operation 0406&#34; and repeat   endlessly______________________________________ 
    
     It is contemplated by the inventors that an additional feature of an operable embodiment would be in disabling the integral term of equation (1) whenever SP 2  is constrained according to equation (5) or (6). The term would be disabled for so long as the constraint applies. The objective is to mitigate the effects of reset wind-up. Signal line 100 in FIG. 2 illustrates the concept. 
     In FIG. 2, whenever the boost limit circuit constrains SP 2 , a signal is provided on signal line 100, which disables the integral mechanism in the unit 54, and which sets a value for C 1 , the integral constant. When SP 2  is constrained, the value for C 1  is given by: 
     
         C.sub.1 =SP.sub.2 -(k.sub.1 e.sub.1 +k.sub.0 SP.sub.1)     (8) 
    
     When C 1  is determined by equation (8), SP 2  is adjusted off of the boost value when: 
     
         SP.sub.1 -H.sub.TC ≦(k.sub.1 e.sub.1 +C.sub.1 +k.sub.0 SP.sub.1)≦SP.sub.1 +H.sub.TB                       (9) 
    
     The conditions of equations (8) and (9) are intended generally to apply to the analog embodiment of FIG. 2 in the form of a diode clipper, for example. 
     While I have described a preferred embodiment of my invention, it should be understood that modifications and adapations thereof will occur to persons skilled in the art. Therefore, the protection afforded my invention should only be limited in accordance with the scope of the following claims.