View A0805C101JCT_7653322.PDF datasheet online --- IC-ON-LINE

Datasheet File OCR Text:

nickel barrier multilayer ceramic capacitors page 1 27/04/06 v1.0 features: ? ? multilayer ceramic chip capacitor. ? ? nickel barrier termination. ? ? high performance and reliability. ? ? 0603, 0805, and 1206 case size. code rated voltage a 100 b 16 t 25 u 50 rated voltage part dimension dimensions length (l) width (w) maximum thickness (t) minimum mb minimum g voltage (v) type 1.6 0.1 0.8 0.1 0.20 0.40 6.3 ~ 50 0603 2.0 0.2 1.25 0.1 1.40 0.25 0.70 6.3 ~ 500 0805 3.2 0.2 1.60 0.2 1.52 1.40 6.3 ~ 1000 1206
nickel barrier multilayer ceramic capacitors page 2 27/04/06 v1.0 temperature characteristics code code temperature coefficient operation temperature (c) capacitance change c npo (class i) -55c ~ +125 0 30ppm/c r x7r (class ii) 15% f y5v (class ii) 30c ~ +85 +22% ~ -82% capacitance code code capacitance (pf) 010 1* 1r5 1.5 100 10* 101 100* 102 1000* 103 10000* 222 2200* 472 4700* tolerance code code tolerance (%) j 5 k 10 z +80/-20 ps: * -- two significant digits followed by number of zeros. temperature coefficient (t.c.) vs. proper tolerance applied: npo: for all tolerance x7r+x5r: k+m tolerance y5v+z5u: m+z tolerance termination code code n termination type nickel packaging code code b t packaging type bulk tape and reel standard test conditions tests shall, unless otherwise specified, be carried out at 15 to 35c and rh 45 to 75%.if any doubt and argument has been encounter in judgement, the final test shall be done at 25 2c, rh45 to 55% and 860 ~ 1060mbar. (based on jis standard). disposition if question to the measuring result in judgement, take the capacitor under a specified temperature for 30 minutes at least befo re measurement.
nickel barrier multilayer ceramic capacitors page 3 27/04/06 v1.0 structure ag/pd series number specifications material minimum termination plating thickness ( m) 1 ceramic dielectric ceramic 2 internal electrode ag-pd 3 end terminal ag layer 40 4 ni layer 1.5 - 3.5 5 sn-pb layer or sn layer 3 - 8 bme series number specifications material minimum termination plating thickness ( m) 1 ceramic dielectric ceramic 2 internal electrode ni 3 end termination cu layer 40 4 ni layer 1.5 - 3.5 5 sn-pb layer or sn layer 3 - 8 storing condition and term recommends the storing of products within 6 months at temperature 15 ~ 35c and humidity 70%rh maximum. if the product stored over 6 months, please reconfirm its solderability before use.
nickel barrier multilayer ceramic capacitors page 4 27/04/06 v1.0 performance item performance test or inspection method external appearance no defects which may affect performance visual inspection and dimension measurement voltage proof withstand test voltage without insulation breakdown or other damage dc tested voltage shall be applied for 1 ~ 5 second. charge/discharge current shall not exceed 50ma (ps : ra - rated voltage) insulation resistance npo: 100,000m ? minimum or r x c 1000 ? x f (which ever is smaller) x7r, x5r, y5v, z5u: 10,000m ? minimum or r x c 1000 ? x f (which ever is smaller) apply dc tested voltage for 60 5 minute. (ps : ra - rated voltage) capacitance (cap.) within the specified tolerance measuring frequency: z5u,y5v, x7r, x5r : 1khz 50hz npo: > 1000pf:1khz 50hz. 1000pf:1mhz 100khz. measuring voltage: z5u:0.5v rms. npo: x7r, x5r, y5v:1.0 0.2v rms. dissipation factor (d.f) npo: 30pf: q 1000 < 30pf: q 400 + 20c ps:c: nominal capacitance (pf) x7r, x5r, y5v, and z5u : (maximum value) code temperature coefficient npo x7r/x5r y5v 200v 2.5ra 250v 2.0ra 500v/630v 1.5ra 1kv 1.5ra 1.25ra - rated voltage dc tested voltage < 1kv 1.0 ra 1kv 1kv t.c. 50v 25v 16v 10v x7r/ x5r 2.5% 3.0% 3.5% 5.0% z5u 4.0% - - - y5v 5.0% 7.5% 9.0% 12.5%
nickel barrier multilayer ceramic capacitors page 5 27/04/06 v1.0 item performance test or inspection method temperature characteristic of capacitance temperatures coefficient the temperature coefficient is determined using the capacitance measured in step 3 as a reference. test the specimen from step 1through step 5, the capacitance shall be within the specified tolerance for the capacitance coefficient and capacitance change as left table. solderabiliy new solder to over 95% of termination completely soak both terminal electrodes in solder at specified temperature for 3 0.5 second a. for tin-lead sn/pb) termination product: 235 5c. b. for lead-free (pure sn) termination product: 245 5c. leaching completely soak both terminal electrodes in solder at 270 5c for 40 1second. soldering to heat external appearance no mechanical damage completely immerse both terminations in solder at 270 5c for 10 3 second. leave the capacitors in ambient condition for 2 4 2 hours before measurement. *preconditioning: f(only for class 2): perform a heat treatment at 150 +0-10c for one hour and then let sit for 24 2 hours at room temperature. perform the initial measurement. capacitance change ( ? c/c) npo x7r/x5 r z5u y5v 2.5% or 0.25 pf maximum (whichever is larger) 7.5% 20% 20% df npo: c 30pf : q 1000 c < 30pf:q 400 + 20c ps: c : nominal capacitance (pf) x7r, x5r, y5v, z5u : (maximum value) ir npo: 100,000mw minimum or r x c 1000w x f (whichever is smaller) x7r, x5r, y5v, z5u: 10,000mw minimum or r x c 1000w x f (whichever is smaller) code temperature coefficient 1 base temperature (25c) 2c 2 minimum operation temperature 2c 3 base temperature (25c) 2c 4 minimum operation temperature 2c 5 base temperature (25c) 2c tc operating temperature capacitance change (dc) npo -55 ~ +125c 0 30 (ppm/c) x7r -55 ~ +125c 15% x5r -55 ~ +85c 15% y5v -55 ~ +125c +22% ~ -82% z5u -55 ~ +125c +22% ~ -56% t.c. 50v 25v 16v 10v x7r/ x5r 2.5% 3.0% 3.5% 5.0% z5u 4.0% - - - y5v 5.0% 7.5% 9.0% 12.5%
nickel barrier multilayer ceramic capacitors page 6 27/04/06 v1.0 item performance test or inspection method humidity (steady state) and humidity load external appearance no mechanical damage humidity load: (not apply for the product with rated voltage 250v): apply the rated voltage at temperature 40 2c and humidity 90 to 95%rh for 1000+48/-0 hours. leave the capacitors in ambient condition for the following time before measurement. class 1: 1~2 hours. class 2: 24 2 hours. charge / discharge current shall not exceed 50 ma. preconditioning: (only for class 2): apply the rated dc voltage for 1hour at 40 2c. remove and let sit for 48 4 hours at room temperature. perform initial measurement. humidity (steady state): the test procedure is same as that in humidity load but only without rated voltage applied. capacitance change ( ? c/c) npo: 5% or 0.5 pf maximum (whichever is larger) x7r/x5r: 12.5% y5v: 30% z5u: 30% df npo: c 30pf: q 350 10pf c < 30pf: q 100+2.5c c < 10pf: 200+10c ps: c: nominal capacitance (pf) c < 30pf:q 400 + 20c ps: c : nominal capacitance (pf) x7r, x5r: less than 2 times of initial value y5v and z5u: less than 1.5 times of initial value ir 500m ? minimum or 25 ? *f (which ever is smaller) load life external appearance no mechanical damage apply 2 x rated voltage at maximum operating temperature 2c for 1000 +48/-10 hours. leave the capacitors in ambient condition for the following time before measurement. class i: 1~2 hours class ii: 24 2 hours charge / discharge current shall. not exceed 50 ma. preconditioning: (only for class 2): apply 200% of the rated dc voltage for 1 hour at the maximum operating temperature 3c. remove and let sit for 24 2 hours at room temperature. perform initial measurement. capacitance change ( ? c/c) npo: 3% or 0.3 pf maximum (whichever is larger) x7r/x5r: 12.5% y5v: 30% z5u: 30% df npo: c 30pf : q 350 30pf > :c 10pf: q 275 +205c c < 10pf: q 200 + 10c ps: c : nominal capacitance (pf) x7r, x5r: less than 2 times of initial value y5v and z5u : less than 1.5 times of initial value ir 1000m ? minimum or 50 ? *f (whichever is smaller)
nickel barrier multilayer ceramic capacitors page 7 27/04/06 v1.0 item performance test or inspection method vibration external appearance without distinct damage (not apply for 0402 product) solder the capacitors to the test jig as shown in figure below with ir-reflow method. the capacitor shall be subjected to a simple harmonic motion with the entire frequency range, from 10 to 55 hz and return to 10 hz ,shall be transverse in 1 min. amplitude (total excursion): 1.5mm amplitude tolerance: 15% this motion shall be applied for a period of 2 hours in each of 3 mutually perpendicular directions (a total of 6 hours) capacitance change ( ? c/c) npo: 2.5% or 0.25 pf maximum (whichever is larger) x7r/x5r: 7.5% y5v, z5u: 20% df or q npo: c 30pf : q 1000 c < 30pf:q 400 + 20c ps: c : nominal capacitance (pf) x7r, x5r, y5v, z5u : (maximum value) deflection external appearance no mechanical damage bending strength flexure 1mm capacitance change ( ? c/c) npo: 5% or 0.5 pf maximum (whichever is larger) x7r/x5r: 12.5% y5v: 30% temperature cycle external appearance no mechanical damage (not apply for 0402 product) the capacitor shall be subject 5 cycles according to four heat treatments listed in the following table. then leave the capacitors in ambient condition for the following time before measurement. class ii: 2~24 hours preconditioning: (only for class 2): perform a heat treatment at 150+0-10c for one hour and then let sit for 24 2 hours at room temperature. perform initial measurement. capacitance change ( ? c/c) npo: 2.5% or 0.25 pf maximum (whichever is larger) x7r/x5r: 7.5% y5v: 20% df npo: c 30pf : q 1000 c < 30pf: q 400 + 20c x7r, x5r, y5v and z5u (maximum value) ir 1000m ? minimum or 50 ? *f (whichever is smaller) t.c. 50v 25v 16v 10v x7r/ x5r 2.5% 3.0% 3.5% 5.0% z5u 4.0% - - - y5v 5.0% 7.5% 9.0% 12.5% t.c. 50v 25v 16v 10v x7r/ x5r 2.5% 3.0% 3.5% 5.0% z5u 4.0% - - - y5v 5.0% 7.5% 9.0% 12.5% step temperature (c) duration (minutes) 1 minimum operation temperature 3 30 3 2 room temperature (25c) 2 ~ 5 3 minimum operation temperature 3 30 3 4 room temperature (25c) 2 ~ 5
nickel barrier multilayer ceramic capacitors page 8 27/04/06 v1.0 precaution for handling the multi-layer ceramic chip capacitors, may fall in a short circuit mode or in an open-circuit mode when subjected to severe conditions of electrical, environmental and/or mechanical stress beyond the specified ?ratings? and specified ?condition? in th e catalog and the specifications, resulting in burnout, flaming or glowing in the worst case. so some common sense of application by customer is necessary. here the following article are some key points that need to take attention in application for customer r eference only: operating conditions and circuit design operating temperature range the specified ?operating temperature range? in the catalog is absolute maximum and minimum temperature rating. so in any case, each the capacitor shall be operated within the specified ?operating temperature range?. design of voltage applications the capacitors shall not be operated exceeding the specified ?rated voltage? in the catalog. if voltage ratings are exceeded th e capacitors could result in failure of damage. in case of application of dc and ac voltage to the capacitors, the designed peak voltage shall be within the specified ?rated voltage?. charging and discharging current the capacitors shall not be operated beyond the specified ?maximum charging / discharging current rated? in the specification, application to a low impedance circuit such as a ?secondary power circuit? are not recommended for safety. temperature rise by dielectric loss of the capacitor the ?operating temperature range? mentioned above shall include a maximum surface temperature rise of 20c, which is caused by the dielectric loss of the capacitor and applied electrical stress (such as voltage, frequency and wave form etc.) it is recommended to measure and check ?surface temperature of the capacitor? in your equipment at your estimated / designed maximum ambient temperature. restriction on environmental conditions the capacitors shall not be operated and / or stored under following environmental conditions: (a) to be exposed directly to water or salt water. (b) to be exposed directly to sunlight. (c) under conditions of dew formation. (d) under conditions of corrosive atmosphere such as hydrogen sulfas, sulphurous acid, chlorine, or ammonia etc. (e) under severe condition of vibrations or shock beyond the specified conditions in the specifications. secular change in capacitance (1) peculiar characteristics of ?secular changes in capacitance? are observed in the capacitors (class 2 high dielectric consta nt temperature characteristics ?x7r? and ?y5v?. the ?secular change? shall be considered in your circuit design. (2) the capacitance change, due to the individual characteristics of ceramic dielectric materials applied, can be recovered to the each initial values at shipping by a heat treatment (140 to 150c for 1 hour). design of printed circuit board selection of printed circuit boards when the capacitors are mounted and soldered on an ?aluminium?s substrate has influences on capacitor?s reliability against ?temperatures cycles? and ?heat shock? because of difference of thermal expansion dose not deterioration the characteristics of the capacitors. there are some thermal expansion factor for different kink of pc board material as follows pc board material thermal expansion factor (mm/c) glass epoxy 1.4 x 10 -5 paper phenol 2.2 x 10 -5 composite alumina 6.5 x 10 -6
nickel barrier multilayer ceramic capacitors page 9 27/04/06 v1.0 design of land pattern recommended dimensions of lands. as shown in table 1 and figure 1. note: * too large land required excess amount of solder. ** the dimensions shall be symmetrical. figure 1 recommended land dimensions: size chip dimensions land dimension length (l) width (w) a b c 0603 1.6 0.8 0.70 ~ 1.00 0.80 ~ 1.00 0.60 ~ 0.80 0805 2.0 1.25 1.00 ~ 1.30 1.00 ~ 1.20 0.80 ~ 1.10 1206 3.2 1.6 2.10 ~ 2.50 1.10 ~ 1.30 1.10 ~ 1.30 recommend amount of solder: recommended amount of solder: as shown in figure2. excess amount of solder gives large mechanical stresses to the capacitors / components. figure 2: recommended amount of solde r table 1 dimensions: millimetres
nickel barrier multilayer ceramic capacitors page 10 27/04/06 v1.0 component layout when placing / mounting the capacitors / components near an area which is apt to bend or a grid groove on the pc board. it is advisable to have both electrodes subjected to uniform stresses, or to position the component electrodes at right angles to the grid groove or bending line. figure 3 component layout uneven mounting density o: proper x: improper probability at which the chip capacitor is broken by the stress on pc board break a > b = c > d > e mounting density and spaces placements in too narrow spaces between components may cause ? solder bridges? during soldering. the minimum space between components shall be 0.5mm in view of the positioning tolerances of the mounting machines and the dimensional tolerances of the components and pc boards. applications of solder resist application of solder resist are effective to prevent solder bridges and to control amounts of solder on pc boards ( as shown i n table 2). recommended application examples examples of solder bridges narrow spacing between chip components radial components are directly connected to chip components common lands are close to chip components
nickel barrier multilayer ceramic capacitors page 11 27/04/06 v1.0 precautions for assembly adhesives for mounting (1) selection of adhesives a. the viscosity of an adhesive for mountings shall be such that the adhesive dose not flow off on the land during its curing. b. if the adhesive is too low in its viscosity, mounted components may be out of alignment after or during soldering. c. the adhesives shall not be corrosive or chemically active to the mounted components and the pc boards. d. the amount of adhesive shall be such that the adhesive does not flow off or be out of alignment. e. adhesives for mountings can be cured by ultraviolet or infrared radiation. in order to prevent the terminal electrodes of th e capacitors the curing shall be done at conditions of 180c maximum, for 2 minutes maximum. chip mounting consideration in mounting the capacitors / components on a printed circuit board, any bending and expanding force against them shall be kept minimum to prevent them from being damaged or cracked. following precautions and recommendation shall be observed carefully in the process: (1) maximum stroke of the vacuum nozzle shall be adjusted so that the pushing force to the printed circuit board shall be limit ed to a static of 1 to 3 n (100 to 300 gf) (see figure4). (2) maximum stroke of the nozzle shall be adjusted so that the maximum bending of printed circuit board dose not exceeded 0.5mm (see figure 4) figure 4 (3) the printed circuit board shall be supported by means of adequate supporting pins as shown in fig.5-(b) figure 5
nickel barrier multilayer ceramic capacitors page 12 27/04/06 v1.0 soldering flux and solder (1) solder flux: a. the content of halogen in the soldering shall be 0.2 wt% or less. b. rosin-based and non-activated soldering flux is recommended. (2) water soluble type soldering flux: in case of water soluble type soldering flux being applied, the flux residue on the surface of pc boards may have influences on the reliability of the components and cause deterioration and failures of them. (3) solder: an eutectic solder (sn63:pb37) is recommended. soldering since a multilayer ceramic chip capacitor comes into direct contact with melted solder during soldering. it is exposed to poten tially damaging mechanical stress caused by the sudden temperature change. the capacitor may also be subject to silver migration, and to contamination by the flux. because of these factors, soldering technique is critical. adhere to the following guidelines. hand soldering in hand soldering of the capacitors, large temperature gradient between preheated the capacitors and the tip of soldering iron may cause electrical failures and mechanical damages such as cracking of breaking of the devices. the soldering shall be carefully controlled and carried out so that the temperature gradient is kept minimum with following recommended conditions for hand soldering. recommended soldering conditions: (1) solder: 1mm thread eutectic solder (sn63:pb37) with soldering flux *in the core. *rosin-based, and mom-activated flux is recommended. (2) preheating: the capacitors shall be preheated so that ?temperature gradient? between the devices and the tip of soldering iron is 150c or below. (3) soldering iron: rated power of 20w max with 3mm soldering tip in diameter. temperature of soldering iron tip: 300c maximum. (the required amount of solder shall be melted in advance on the soldering tip.) (4)cooling: after soldering, the capacitors shall cooled gradually at room ambient temperature. flow soldering in flow soldering process, abnormal and thermal and mechanical stresses, caused by ?temperature gradient? between the mounted capacitors, resulting in failures and damages of the capacitors. so it is essential that the soldering process shall controlled to the following recommended conditions and precautions. (see figure 6) figure 6 recommended soldering temperature time profile (flow soldering)
nickel barrier multilayer ceramic capacitors page 13 27/04/06 v1.0 (1) application of flux: the soldering flux(3.3) shall applied to the mounted capacitors thinly and uniformly by forming method. (2) preheating: the mounted capacitors / components shall be preheated sufficiently so that the ? temperature gradient? between the capacitors / components and the melted solder shall be 150c or below. (3) immersion to soldering bath: the capacitors shall be immersed into a soldering bath of 240 to 250c for 3 to 5 seconds. (4)cooling: the capacitors shall be cooled gradually to room ambient temperature with the cooling temperature rates of 8c/s maximum from 250c to 170c and 4c/s maximum from 170c to 130c. (5) flux cleaning: when the capacitors are immersed into cleaning solvent, it shall be confirmed that the surface temperature of devices do not ex ceed 100c (see 3.5). reflow soldering. i n reflow soldering process, the mounted capacitors / components are generally heated and soldering by a thermal conduction system such as an ?infrared radiation and hot blast soldering system? or a ?vapour phase soldering system (vps)?, large temperature gradients such as a rapid heating and cooling in the process may cause electrical and mechanical damages if the device. it is essential that the soldering process shall be controlled by following recommended conditions and precaution. (see figure7) for tin-lead (sn/pb) termination component : (1) preheating 1. the mounted capacitors / components shall be preheated sufficiently, for 60 to 90 seconds so that the surface temperature of th em to be 140 to 150c. (2) preheating 2. after ?preheating 1?, the mounted capacitors / components shall be the elevated temperature of 150 to 200c for 2 to 6 seconds. (3) soldering: the mounted capacitors / components shall be heated under the specified heating conditions (200 to 240 to 200c for total 20 to 40 seconds, see figure7 ) and shall be soldered at the maximum temperature of 240c for 10 seconds of less. (4)cooling: after the soldering, the mounted capacitors / components shall be gradually cooled to room ambient temperature for preventing mechanical damages such as cracking of the devices. (5) flux cleaning: when the mounted capacitors / components are immersed into cleaning solvent, it shall be confirmed the surfaces temperatures of them do not exceeding 100c. note: if the mounted capacitors / components are partially heated in the soldering process, the devices may be separated form t he printed circuit board by the surface tension of partially melted solder, and stand up like a ?tomb stone?. figure 7 recommended soldering temperature time profile for tin-lead component (reflow soldering)
nickel barrier multilayer ceramic capacitors page 14 27/04/06 v1.0 for lead-free (pure tin plating termination) termination component essentially, the soldering temperature for lead-free component is a little higher than that for tin-lead component, but need to take consideration of the thermal effect for all other components mounting on board at the same time. the below picture is a recommended soldering profile for lead-free component figure 8 recommended soldering temperature time profile for lead-free component (reflow soldering) post soldering cleaning (1)residues of corrosive soldering fluxes on the pc board after cleaning may greatly have influences on the electrical characte ristics and the reliability, (such as humidity resistance) of the capacitors, which have been mounted on the board. it shall be confirm ed that the characteristic and reliability at the devices are no effected by applied cleaning conditions. (2) solubility of alternative cleaning solvent such as alcohol etc., is inferior to that of freon cleaning solvent in the flux cleaning. so in case of alternative cleaning solvents, fresh cleaning solvent shall be used, and sufficient rinsing and drying shall carried ou t. (3) when an ultrasonic cleaning is applied to the mounted capacitors on pc board, following conditions energy and the recommended for preventing failures or damages of the devices due to the large vibration energy and the resonant caused by the ultrasonic waves. frequency :29khz maximum. radiated power :20 w/litre maximum. period :5 minutes maximum. process inspection when the mounted printed circuit are inspected with measuring terminal pins, abnormal and excess mechanical stresses shall not be applied to the pc board mounted components, to prevent failure or damages of the devices. (1) the mounted pc board shall be supported a same adequate supporting pins prevent their banding. (2) it shall be confirmed that the measuring pin have the right tip in shape, equal in height and are set in the tight position s. (3) the amount of adhesive shall be such that the adhesive dose flow off or be out of alignment. protective coating when the surface of a printed board on which the capacitors has been mounted is coated with resin to protect against moisture a nd dust, it shall be confirmed that the protective coat dose not have influences on reliability of the capacitors in the actual eq uipment. (1) coating materials, such as being corrosive and chemically active, shall not be applied to the capacitors and other componen ts. (2) coating materials with a large expansively shall not be applied to the capacitors for preventing failures or damages (such as cracking) of the devices in the curing process.
nickel barrier multilayer ceramic capacitors page 15 27/04/06 v1.0 dividing / breaking of pc boards (1) abnormal and excessive mechanical stresses, such as bending or expanding force on the components on the printed circuit board, shall be kept minimum in the dividing / breaking. (2) dividing / breaking of the pc board shall be done carefully at moderate speed using a jig boards from mechanical damages. long term storage the capacitors shall not be stored under severe conditions of high temperatures and high humidity. store them under 40c maximum and 75%rh maximum use them within 6 months and check the solderability before use. part number table type voltage (v) temperature characteristics code part number 0603 10 f n0603f474zct n0603f474znt 16 r b0603r104kct b0603r104knt 25 t0603r223kct t0603r473kct t0603r223knt t0603r473knt f t0603f104zct t0603f104znt 50 c u0603c220jct u0603c101jct u0603c221jct u0603c102jct u0603c100jnt u0603c220jnt u0603c470jnt u0603c101jnt u0603c221jnt u0603c331jnt u0603c471jnt u0603c102jnt r u0603r102kct u0603r103kct u0603r471knt u0603r102knt u0603r222knt u0603r332knt u0603r472knt u0603r103knt f u0603f103znt u0603f473znt
nickel barrier multilayer ceramic capacitors page 16 27/04/06 v1.0 part number table type voltage (v) temperature characteristics code part number 0805 10 r n0805r105kct n0805r105knt 16 b0805r224kct b0805r334kct b0805r474kct b0805r224knt b0805r334knt b0805r474knt 25 f t0805f105zct t0805f105znt 50 c u0805c102jct u0805c222jct u0805c102jnt u0805c222jnt r u0805r102kct u0805r103kct u0805r223kct u0805r473kct u0805r104kct u0805r102knt u0805r222knt u0805r472knt u0805r103knt u0805r223knt u0805r473knt u0805r104knt f u0805f104zct u0805f104znt 100 c a0805c100jct a0805c220jct a0805c330jct a0805c470jct A0805C101JCT a0805c221jct a0805c471jct a0805c100jnt a0805c220jnt a0805c330jnt
nickel barrier multilayer ceramic capacitors page 17 27/04/06 v1.0 part number table type voltage (v) temperature characteristics code part number 0805 100 c a0805c470jnt a0805c101jnt a0805c221jnt a0805c331jnt a0805c471jnt 1206 10 r n1206r225kct n1206r225knt 16 b1206r105kct b1206r105knt f b1206f225zct b1206f225znt 25 c t1206c472jct t1206c103jct t1206c472jnt t1206c103jnt r t1206r334kct t1206r474kct t1206r334knt t1206r474knt 50 u1206r103kct u1206r104kct u1206r102knt u1206r222knt u1206r332knt u1206r472knt u1206r103knt u1206r223knt u1206r333knt u1206r473knt u1206r104knt f b1206f475zct b1206f475znt 100 c a1206c100jct a1206c220jct a1206c101jct a1206c221jct a1206c331jct
nickel barrier multilayer ceramic capacitors page 18 27/04/06 v1.0 part number table type voltage (v) temperature characteristics code part number 1206 100 c a1206c471jct a1206c102jct a1206c100jnt a1206c220jnt a1206c330jnt a1206c470jnt a1206c101jnt a1206c221jnt a1206c331jnt a1206c471jnt a1206c102jnt part number explanation u 0805 c 102 j n t rated voltage part dimension temperature characteristics code capacitance code tolerance code termination code packaging code rated voltage : a, b, t and u. part dimension : 0603, 0805 and 1206. temperature characteristics code : c, r and f. capacitance code : 100, 101, 102, 103 and 472. tolerance code : j, k and z. termination code : termination type. packaging code : packaging type.

▲Up To Search▲

Price & Availability of A0805C101JCT

	To Download A0805C101JCT Datasheet File
If you can't view the Datasheet, Please click here to try to view without PDF Reader .