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本文(ASTM F773M-2016 Standard Practice for Measuring Dose Rate Response of Linear Integrated Circuits (Metric)《线性集成电路的剂量率响应测量的标准实施规程 (米制)》.pdf)为本站会员(eventdump275)主动上传,麦多课文库仅提供信息存储空间,仅对用户上传内容的表现方式做保护处理,对上载内容本身不做任何修改或编辑。 若此文所含内容侵犯了您的版权或隐私,请立即通知麦多课文库(发送邮件至master@mydoc123.com或直接QQ联系客服),我们立即给予删除!

ASTM F773M-2016 Standard Practice for Measuring Dose Rate Response of Linear Integrated Circuits (Metric)《线性集成电路的剂量率响应测量的标准实施规程 (米制)》.pdf

1、Designation: F773M 16Standard Practice forMeasuring Dose Rate Response of Linear IntegratedCircuits (Metric)1This standard is issued under the fixed designation F773M; the number immediately following the designation indicates the year oforiginal adoption or, in the case of revision, the year of las

2、t revision. A number in parentheses indicates the year of last reapproval. Asuperscript epsilon () indicates an editorial change since the last revision or reapproval.1. Scope1.1 This practice covers the measurement of the response oflinear integrated circuits, under given operating conditions, topu

3、lsed ionizing radiation. The response may be either transientor more lasting, such as latchup. The radiation source is eithera flash X-ray machine (FXR) or an electron linear accelerator(LINAC).1.2 The precision of the measurement depends on thehomogeneity of the radiation field and on the precision

4、 of theradiation dosimetry and the recording instrumentation.1.3 The test may be considered to be destructive either forfurther tests or for other purposes if the total radiation ionizingdose exceeds some predetermined level or if the part shouldlatch up. Because this level depends both on the kind

5、ofintegrated circuit and on the application, a specific value mustbe agreed upon by the parties to the test. (See 6.10.)1.4 Setup, calibration, and test circuit evaluation proceduresare included in this practice.1.5 Procedures for lot qualification and sampling are notincluded in this practice.1.6 B

6、ecause response varies with different device types, thedose rate range and device upset conditions for any specific testis not given in this practice but must be agreed upon by theparties to the test.1.7 The values stated in SI units are to be regarded asstandard. No other units of measurement are i

7、ncluded in thisstandard.1.8 This standard does not purport to address all of thesafety concerns, if any, associated with its use. It is theresponsibility of the user of this standard to establish appro-priate safety and health practices and determine the applica-bility of regulatory limitations prio

8、r to use.2. Referenced Documents2.1 ASTM Standards:2E666 Practice for Calculating Absorbed Dose From Gammaor X RadiationE668 Practice for Application of Thermoluminescence-Dosimetry (TLD) Systems for Determining AbsorbedDose in Radiation-Hardness Testing of Electronic DevicesE1894 Guide for Selectin

9、g Dosimetry Systems for Applica-tion in Pulsed X-Ray SourcesF526 Test Method for Using Calorimeters for Total DoseMeasurements in Pulsed Linear Accelerator or FlashX-ray Machines3. Terminology3.1 Definitions:3.1.1 dose rateenergy absorbed per unit time and per unitmass by a given material from the r

10、adiation to which it isexposed.3.1.2 dose rate induced latchupRegenerative device ac-tion in which a parasitic region (e.g., a four (4) layer p-n-p-n orn-p-n-p path) is turned on by a photocurrent generated by apulse of ionizing radiation and remains on for an indefiniteperiod of time after the phot

11、ocurrent subsides. The device willremain latched as long as the power supply delivers voltagegreater than the holding voltage and current greater than theholding current. Latchup may disrupt normal circuit operationin some portion of the circuits, and may also cause catastrophicfailure due to local

12、heating of semiconductor regions, metalli-zations or bond wires.3.1.3 dose rate responsethe change that occurs in anobserved characteristic of an operating linear integrated circuitinduced by a radiation pulse of a given dose rate.3.1.4 latchup windowA latchup window is the phenom-enon in which a de

13、vice exhibits latchup in a specific range ofdose rates. Above and below this range, the device does notlatchup. A device may exhibit more than one latchup window.This phenomenon has been infrequently observed for some1This practice is under the jurisdiction of ASTM Committee F01 on Electronicsand is

14、 the direct responsibility of Subcommittee F01.11 on Nuclear and SpaceRadiation Effects.Current edition approved May 1, 2016. Published May 2016. Originallyapproved in 1982. Last previous edition approved in 2010 as F773M 10. DOI:10.1520/F0773M-16.2For referenced ASTM standards, visit the ASTM websi

15、te, www.astm.org, orcontact ASTM Customer Service at serviceastm.org. For Annual Book of ASTMStandards volume information, refer to the standards Document Summary page onthe ASTM website.Copyright ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States

16、1complementary metal-oxide-semiconductor (CMOS) memo-ries and may occur in other devices.3.1.5 upset thresholdThe minimum dose rate at which thedevice upsets. However, the reported measured upset thresholdshall be the maximum dose rate at which the device does notupset and which the transient distur

17、bance of the outputwaveform and or supply current remains within the specifiedlimits.4. Summary of Practice4.1 The test device and suitable dosimeters are irradiated bya pulse from either an FXR or a LINAC while the test deviceis operating under agreed-upon conditions. The responses ofthe test devic

18、e and of the dosimeters are recorded.4.2 The response of the test device to dose rate is recordedover a specified dose rate range.4.3 A number of factors are not defined in this practice, andmust be agreed upon beforehand by the parties to the test.4.3.1 Total dose limit (see 1.3),4.3.2 Electrical p

19、arameters of the test device whose re-sponses are to be measured (see 10.10),4.3.3 Temperature at which the test is to be performed (see6.7),4.3.4 Details of the test circuit, including output loading,power supply levels, and other operating conditions (see 7.4and 10.3),4.3.5 Choice of radiation pul

20、se source (see 6.9 and 7.9),4.3.6 Pulse width (see 6.9 and 7.9.2),4.3.7 Sampling (see 8.1),4.3.8 Need for total ionizing dose measurement (see 6.10,7.8, and 10.1.1),4.3.9 An irradiation plan which includes the dose rate rangeand the minimum number of dose rate values to be used in thatrange (see 10.

21、6 and 10.9), and4.3.10 Appropriate functional test (see 10.4 and 10.8).5. Significance and Use5.1 There are many kinds of linear integrated circuits. Anygiven linear integrated circuit may be used in a variety of waysand under various operating conditions within the limits ofperformance specified by

22、 the manufacturer. The procedures ofthis practice provide a standardized way to measure thedose-rate response of a linear integrated circuit, under operat-ing conditions similar to those of the intended application,when the circuit is exposed to pulsed ionizing radiation.5.2 Knowledge of the respons

23、es of linear integrated circuitsto radiation pulses is essential for the design, production, andmaintenance of electronic systems that are required to operatein the presence of pulsed radiation environments.6. Interferences6.1 Air IonizationA spurious component of the signalmeasured during a test ca

24、n result from conduction through airionized by the radiation pulse. Such spurious contributions canbe checked by measuring the signal while irradiating the testfixture in the absence of a test device. Air ionization contribu-tions to the observed signal are generally proportional to theapplied field

25、, while those due to secondary emission effects(6.2) are not. The effects of air ionization external to the devicemay be minimized by coating exposed leads with a thick layerof paraffin, silicone rubber, or nonconductive enamel, or bymaking the measurement in a vacuum.6.2 Secondary EmissionAnother s

26、purious component ofthe measured signal can result from charge emission from, orcharge injection into, the test device and test circuit.3This maybe minimized by shielding the surrounding circuitry andirradiating only the minimum area necessary to ensure irradia-tion of the test device. Reasonable es

27、timates of the expectedmagnitude of current resulting from secondary-emission effectscan be made based on the area of metallic target materialsirradiated.NOTE 1For dose rates in excess of 108Gy(Si)/s, the photocurrentsdeveloped by the package may dominate the device photocurrent. Careshould be taken

28、 in the interpretation of the measured photoresponse forthese high dose rates.Values of current density per unit dose rate generally rangebetween 1011and 1010A/cm2per Gy(Si)/s. The use of ascatter plate (7.9.2) may increase these values.6.3 OrientationThe effective ionizing dose to a semicon-ductor

29、junction can be altered by changing the orientation ofthe test device with respect to the irradiating beam. Mostintegrated circuits may be considered “thin samples” (in termsof the range of the radiation). However, some devices mayhave cooling studs or thick-walled cases that can act to scatterthe i

30、ncident beam, thereby modifying the dose received by thesemiconductor chip. Position such devices carefully with thedie normal to the beam.6.4 Dose EnhancementHigh atomic number materialsnear the active regions of the integrated circuit (package,metallization, die attach materials, etc.) can deliver

31、 an en-hanced dose to the sensitive regions of the device due tosecondary electron emission from the high atomic numbermaterial when it is irradiated with an FXR. The possibility andextent of this effect should be considered.6.5 Electrical NoiseSince radiation test facilities are in-herent sources o

32、f RF noise, noise-minimizing techniques suchas single-point ground, filtered dc supply lines, etc., must beused in these measurements (see Fig. 1).6.6 DosimetryAccurate, reproducible calibration of dose-rate monitors is difficult. For this reason, dosimetry is apt toprovide the single most significa

33、nt source of error in dose-ratedeterminations.6.7 TemperatureDevice characteristics are dependent onjunction temperature; hence, the temperature of the test shouldbe controlled. Unless otherwise agreed upon by the parties tothe test, dose rate testing shall be performed at 24 6 6C.(Temperature shoul

34、d be specified in the test plan or testprocedure).3Sawyer, J. A., and van Lint, V. A. J., “Calculations of High-Energy SecondaryElectron Emission,” Journal of Applied Physics, Vol 35, No. 6, June 1964, pp.17061711.F773M 1626.8 Beam Homogeneity and Pulse-to-Pulse RepeatabilityThe intensity of a beam

35、from an FXR or a LINAC is likely tovary across its cross section. Since the pulse-shape monitor isplaced at a different location than the device under test, themeasured dose rate may be different from the dose rate towhich the device was exposed. The spatial distribution andintensity of the beam may

36、 also vary from pulse to pulse. Thebeam homogeneity and pulse-to-pulse repeatability associatedwith a particular radiation source should be established by athorough characterization of its beam prior to performing ameasurement.6.9 Pulse WidthThe response observed in a dose rate testmay be dependent

37、on the width of the radiation pulse. This factmust be considered when selecting a radiation source, or whencomparing data taken at different times or at different radiationtest facilities.6.10 Total Ionizing DoseEach pulse of the radiationsource imparts an ionizing dose to both the device under test

38、and the device used for dosimetry. The total ionizing doseaccumulated in a semiconductor device will cause permanentdamage which can change its operating characteristics. As aresult, the response that is measured after several pulses maybe different from that characteristic of an unirradiated device

39、.Care should be exercised to ensure that the total ionizing dosedelivered to the test device is less than the agreed-uponmaximum value. Care must also be taken to ensure that thecharacteristics of the dosimeter have not changed due to theaccumulated dose.7. Apparatus7.1 Regulated DC Power Supplies w

40、ith floating outputs toproduce the voltages required to bias the integrated circuitunder test.7.2 Recording Devicessuch as digital storage oscillo-scopes or other suitable instruments. The bandwidth capabili-ties of the recording devices shall be such that the radiationresponses of the integrated ci

41、rcuit and the pulse-shape monitor(7.6) are accurately displayed and recorded.NOTE 2Depending on the kind of measurement, dc instruments,spectrum analyzers, current transformers, or other instruments may berequired to measure and record the response of the test device.7.3 Cabling, to ensure an adequa

42、te electrical connection ofthe test circuit in the exposure area with the power supply andrecording devices in the data area. Shielded twisted pair orcoaxial cables may be used to connect the power supplies to thebias points of the test circuit; however, coaxial cables properlyterminated at the reco

43、rding device inputs are required for thesignal leads.7.4 Test Circuit, as shown in Fig. 1. Although the details oftest circuits for this test must vary depending on the kind ofelectronic component tested and on the specific electricalparameters of the test device to be measured, the example ofFig. 1

44、 provides the information necessary for the design of atest circuit for most purposes. The capacitor, C1(typically 10F), provides an instantaneous source of current as may berequired by the test device during the radiation pulse. Its valuemust be large enough that the decrease in the supply voltaged

45、uring a pulse is less than 10 %. Capacitor C1should be placedin parallel with a small (approximately 0.1 F) low-inductancecapacitor, C2, to ensure that possible inductive effects of thelarge capacitor are offset. Both capacitors must be located asclose to the test device as possible, consistent with

46、 the spaceneeded for any shielding that may be necessary. The arrange-ment of the grounding connections provides that there are noground loops and that only one ground exists. This reducesboth the possibility of ground loops and common-mode signalspresent at the terminals of the measurement instrume

47、nts. Theresistors, R0, are terminations for the coaxial cables, and havevalues within2%ofthecharacteristic impedances of theirrespective cables. All unused inputs to the test device areFIG. 1 Example of a Test CircuitF773M 163connected as agreed upon by the parties to the test. Theoutput(s) of the t

48、est device may be loaded, as agreed upon bythe parties to the test. To prevent loading of the output of thetest device by the coaxial cable, line drivers having a high inputimpedance and adequate bandwidth, linearity, and dynamicrange may be used to reproduce accurately at the output end ofthe coaxi

49、al cable the waveforms appearing at the line driverinputs.7.5 Signal Sourcesas required to provide the agreed-uponoperating conditions of the test device and to perform suitablefunctional tests.7.6 Radiation Pulse-Shape MonitorOne of the followingapproaches to develop a signal proportional to the dose ratedelivered to the test device should be employed.7.6.1 Fast Signal-Diode in the circuit configuration of Fig.2. The resistors, R1, serve as high frequency isolation and mustbe at least 20 . The capacitor, C1(typically 10 F), suppliesthe charge during th

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