GQM1885C2A2R2BB01D Murata, GQM1885C2A2R2BB01D Datasheet - Page 13
GQM1885C2A2R2BB01D
Manufacturer Part Number
GQM1885C2A2R2BB01D
Description
CAPACITOR, NP0, 0603, 2.2PF
Manufacturer
Murata
Series
GQMr
Datasheet
1.GQM1885C2A3R9BB01D.pdf
(30 pages)
Specifications of GQM1885C2A2R2BB01D
Capacitance
2.2pF
Capacitance Tolerance
± 0.1pF
Voltage Rating
100VDC
Capacitor Dielectric Type
Ceramic Multi-Layer
Capacitor Case Style
0603
No. Of Pins
2
Lead Spacing
0.5mm
Operating Temperature
RoHS Compliant
Operating Temperature Range
-55°C To +125°C
Svhc
No SVHC (15-Dec-2010)
Rohs Compliant
Yes
Tolerance
0.1 pF
Temperature Coefficient / Code
C0G (NP0)
Package / Case
0603 (1608 metric)
Product
Low ESR MLCCs
Dimensions
0.8 mm W x 1.6 mm L x 0.8 mm H
Termination Style
SMD/SMT
Lead Free Status / Rohs Status
Details
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
Company:
Part Number:
GQM1885C2A2R2BB01D
Manufacturer:
MURATA
Quantity:
640 000
32 – Innovator in Electronics
Application Specific Capacitors
High Frequency Ceramic Capacitors – GQM Series
GQM Specifications and Test Methods
Specifications and Test Methods
Item
Operating Temperature
Appearance
Dimension
Dielectric Strength
Insulation Resistance
Q
Adhesive Strength of
Termination
Vibration Resistance
Deflection
Solderability of Termination
Resistance to Soldering Heat
Temperature Cycle
Humidity Steady State
Humidity Load
Capacitance
Temperature
Characteristics
−55°C to 125°C
No defects or abnormalities.
Within the specified dimensions.
No defects or abnormalities.
More than 10,000MΩ or 500Ω・F .
30pFmin.: Q 1400
30pFmax.: Q 800+20C
C:Nominal Capacitance (pF)
No removal of the terminations or other
defect should occur.
Appearance: No defects or abnormalities.
Capacitance: Within the specified tolerance.
30pFmin.: Q 1400
30pFmax.: Q 800+20C
C: Nominal Capacitance (pF)
No crack or marked defect should occur.
75% of the terminations are to be soldered
evenly and continuously.
Appearance: No marking defects
Capacitance Change Within ±2.5% or
±0.25 pF(Whichever is larger)
30pFmin.: Q 1400
30pFmax.: Q 800+20C
C: Nominal Capacitance (pF)
Appearance: No marking defects
Capacitance Change Within ±2.5% or
± 0.25 pF (Whichever is larger)
30pFmin.: Q 1400
30pFmax.: Q 800+20C
C:Nominal Capacitance (pF)
Appearance: No marking defects
Capacitance Change Within ±5% or
± 0.5pF (Whichever is larger)
30pFmin.: Q 350
10pF - 30pF: Q 275+5C/2
10pFmax.: Q 200+10C
C: Nominal Capacitance (pF)
Appearance: No marking defects
Capacitance Change Within ±7.5% or
±0.75 pF (Whichever is larger)
Capacitance Change:
Within the specified tolerance. (Table A-1)
Temperature Coefficent:
Within the specified tolerance. (Table A-1)
Capacitance Drift: Within ±0.2% or
±0.5pF (Whichever is larger)
w
w
w
Specification
w
w
w
w
w
w
.
.
m
m
.
m
u
u
u
r
r
r
a
a
a
t
t
Reference Temperature: 25°C
Visual inspection.
Using calipers.
250% of the rated voltage
DC voltage not exceeding the rated voltage at 25°C
and 75%RH max. and within 2 minutes of charging.
Frequency 1±0.1MHz
Voltage 0.5 to 5Vrms
Solder the capacitor to the test jig (glass epoxy
board) then apply10N force in parallel with the test jig
for 10±1sec.
Frequency range, from 10 to 55Hz and return to
10Hz, should be traversed in approximately 1 minute.
This motion should be applied for a period of 2 hours
in each of 3 mutually perpendicular directions total of
6 hours).
Flexure: 1mm
Immerse in eutectic solder solution for 2±0.5 seconds
at 230±5°C or Sn-3.0Ag-0.5Cu solder solution for
2±0.5 seconds at 245±5°C .
Immerse the capacitor in a eutectic solder solution or
Sn-3.0Ag-0.5Cu solder solution at 270±5°C for
10±0.5 seconds. Let sit at room temperature for 24±2
hours
−55°C to 125°C Five cycles
40±2°C and 90 to 95% humidity for 500±12 hours.
Apply the rated voltage at 40±2°C and 90 to 95%
The temperature coefficient is determined using the
capacitance measured in step 3 as a reference.
When cycling the temperature sequentially from
step 1 through 5 the capacitance should be within
the specified tolerance for the temperature coefficient
and capacitance change as in Table A-1. The
capacitance drift is calculated by dividing the
differences between the maximum and minimum
measured values in steps 1, 3 and 5 by the cap.
value in step 3.
a
a
t
Step
1
2
3
4
5
a
.
.
c
c
.
c
o
o
o
m
m
Test Method
m
Temperature ( C)
125 3
-55 3
25 2
25 2
25 2
GQM Series
C-29-C
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