IC- Types M...

M51516 12W- Lautsprecherverstärker

Pinbelegung:
1 : Input A
2 : Gnd Kleinsignalseite
3 : Muting
4 : Feedback 1 = Inv Input A
5 : Feedback 2 = Inv Input B
6 : Gnd
7 : Output B
8 : Output A
9 : Vcc = +9 bis +16 V, max 18V, max 25V ohne NF-Ansteuerung

Lastwiderstand 4 Ohm zwischen Pin 7 und 8, interne 
  Kurzschlußsicherung.
Ruhestrom bei 13,5 V : typ 80 mA, max 200 mA
  bei 18V : typ 105 mA

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M5230L  Variable output voltage regulator,
 dual tracking type, current limiting, thermal shutdown.
From a MITSUBISHI datasheet:

Pins : Single In Line
1 : Gnd
2 : Balance adjustment (R to Pin6 and R to Pin3 )
3 : (-) output
4 : (-) input
5 : Voltage adjustment (R to Pin6 and R to Pin1 )
6 : (+) 0utput
7 : (+) input
8 : Output control 
If pin 8 is connected via 1 MOhm to + V in : both outputs are
switched off. If pin 8 is shorted to Gnd via a NPN Transistor
or if left open (not connected): Regulators ON.

Absolute Maximum Ratings :
Vin = +/-35 V
I load = +/- 30 mA
Vin - Vout voltage difference : +/- 32 V
Pd = 800 mW
T op = -20 to 75 grdC.

Characteristics :
Input Voltage : min +/- 8 V, max +/- 35 V
Output Voltage: min +/- 3 V, max +/- 30 V 
Min. Vin - Vout Drop at I load =10 mA : typ 2.5 V, max 3 V
Current Limiting to 55mA
Bias Current (without load , without resistor current):
   typ 1.3, max 3 mA
Reference Voltage between Pin 5 and Pin1 : 
   min 1.66V, typ 1.8V, max 1.95V 

  Pin 5 is an Input of a Diff. Ampl. having the other Base 
connected to the internal reference. Therefore one can measure 
the 1.8V only if the regulator works well.

  Often the problems are caused by the electrolyte capacitors.
The IC must see 10 uF to Gnd at each input and output. If a 
capacitor is too old, the IC becomes instabile and the 
reference comparator detects the peak amplitude instead of 
dc output.

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Without guaranty! Mistakes are possible. Please ask via email if you find a strange value!

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M54462P  1/64, 1/256 ECL Divider, TTL- Output

Pins for the Plastic Dual In Line Case:
1 : Vcc
2 : Vcc
3 : nc = no connecion
4 : Output
5 : nc
6 : Gnd
7 : Gnd
8 : nc
9 : nc
10: Input
11: nc
12: nc
13: Vref Input
14: Divider Selection Input: high for 1/64, low for 1/256

For the L- case I don't possess the pinning.

Maximum Ratings:
Vcc = 7 V
Vin = 2.5 V
Top = -10...75 grdC.

Characteristics at Vcc=5 V, 25 grdC. :
Supply Current : min 30 mA, typ 50 mA, max 80 mA
Input Sensitivity at 80...950 MHz : max 100 mV peak-peak
  Recommended Input Voltage : max 600 mV pp
Divider Selection Input : Vih = max Vcc - 0.3 V
   Vil = max 0.5 V
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M54475P 2- Modulus ECL Divider with ECL Output

1/64, 1/65, 1/128, 1/129

Pins :
1 : Vcc
2 : Input  1)
3 : NC
4 : Gnd
5 : Output
6 : Divide Select 64-/128
7 : Modulus Control Input
8 : Vref   1)

1) Pins 2 and 8: Bases of a differential input amplifier. Both having 
internal 250 Ohm resistors to the internal Vref- generator. Pin 8 with 
internal (Cap.-) diodes to Vcc and from Gnd (external 1 nF recommended)

Truth Table:
64-/128   Modulus    selected div.ratio
   H         H          1/64
   H         L          1/65
   L         H          1/128
   L         L          1/129

Absolute Maximum Ratings:
Vcc : -0.5 to +7 V
Inputs: -0.5 to Vcc
Output Current : -10 mA
Pd at 75 grdC. : 400 mW
Top : -20 to +75 grdC.
Tstg : -55 to +125 grdC.

Recommendet Operating Conditions :
Vcc : min 4.5, typ 5, max 5.5 V
Input Frequency at Vin=400mV pp : min 100 MHz, max 1000 MHz
Input Amplitude: min 0.4 V pp, max 1.2 V pp (Peak-Peak)
Io : max 5 mA
Output Load Cap.: max 15 pF

Characteristics:
Pin 7 (Modulus): Vih : min 2 V, max Vcc
                 Vil : min 0, max 0.8 V
      Iih at Vin=Vcc=5.5V : max 30 uA
      Iil at Vin = 0 : min -20 uA
      Set up time at Fin=1000MHz : max 20 ns
Output Aplitude at C load=15 pF (including the probe): 
      min 0.9 V, typ 1.2 V
Supply Current at Vcc=5.5V : typ 40 mA, max 60 mA

I think the prescaler will oscillate at ~900MHz if without input signal. 
For this frequency the sensitivity- diagram has a peak.
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M54530P 7 unit 400mA NPN Darlington Transistor Array. 

From the Input Pin to Base: 20 kOhm
From each Base to Gnd : 20 kOhm
There is a Diode ( max Vr=40V, max If=400mA ) from each open
 Collector Output to pin 9.

Pins:
1 ...7 : Inputs
8 : Gnd
9 : COM
10: Out 7
...
16: Out 1

Maximum Ratings:
Vceo : -50... +40 V
Ic : 400 mA
Vi : 40 V
Pd : 1.47 W
Top : -20... 75 grdC.

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M54959P PLL frequency synthesizer
 From a 7- page datasheet by Mitsubishi 1988.

Pins :
1 : f in (max 500MHz)
2 : Reference Bias for f in (100 pF to Gnd)
3 : Reset for the data transfer 21-pulse counter
4 : /CPS = Clock Pulse Input
5 : SI Data Input for shift register
6 : SW1 Open Collector Output
7 : SW2 
8 : Gnd
9 : PD = Phase detector output, Three-state
10: /LOCK, low when PLL locked
11: P/N Phase detector polarity switching
12: not connected
13: Test input
14: X out Chrysal Oszillator 12.8 MHz
15: X in
16: Vcc

Data Input at Pin 5 is read by the falling edge of /CPS.
  The Pulse 22.. is ignored.
The FIRST pulse is for D21, MSB of Shift Register.
 ( I don't know if it is usually)
Shift Register location 1 (LSB) to 7 : A0 to A6 of the 
  Swallow Counter Division Ratio.
Shift Register location 8 to 17 : N0 to N9 of the
  Main Counter Division Ratio.

Total Division Ratio = A + 128 N

Shift Register location 18, 19: 
DA, DB Reference Frequency Selection:
  L  L  = 50 kHz for a 12.8 MHz crystal
  H  L  = 15 kHz
  L  H  = 12.5 kHz
  L  L  =  6.25 kHz
Location 20 : SW1
Location 21 : SW2

The data must be stable min 10 us before the negative going 
/CPS impulse and 10 us Hold-Time.
Enable Time from RST to /CPS : min 20 us

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MAB8442 Microcontroller

The MAB8442 is hidden on the datasheet of the MAB8422.

For the MAB8422/8442 8bit Microcontroller with 2k/4kx8 ROM 
and 64/128 bytes RAM I have an 18 page datasheet in the 
PHILIPS Databook 1988.

Replacement in your heater is difficult, because of the 
special software in the ROM of the Microcontroller.

Pins:
1 to 8: 8 bit quasi bidirectional I/O Port
9 : T0,/INT : external Interrupt Input, Test Input for 
      JTO or JNT0 instructions.
10: Gnd
11: T1 (as T0)
12: XTAL1
13: XTAL2
14: RESET
15 to 17: Quasi bidirectional port
18: SCL for I2C-bus or as Pin 15
19: SDA for I2C-bus or as Pin 15
20: Vcc

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MB3614 Quad Operational Amplifier
From the 3- page datasheet in the FUJITSU databook LINEAR 1997

The MB3614 is very similar to the LM 324 
( available from many Second-Sources )

Pins:
1 : OutA
2 : -InA
3 : +InA
4 : Vcc
5 : +InB
6 : -InB
7 : OutB
8 : OutC
9 : -InC
10: +InC
11: Gnd
12: +InD
13: -InD
14: OutD

Absolute Maximum Ratings:
Vcc : 36V
Differential Input Voltage : 36 V
Input Common Mode Voltage : -0.3 to 36 V
Pd = 570 mW
Top = -20 to 75 grdC.  ( LM 324 has 0 to 70 grdC.! )
Tstg = -55 to 125 grdC.

Characteristics:
Input Offset Voltage : typ 2 mV, max 7 mV
Input Offset Current : typ 5 nA, max 50 nA
Input Bias Current : typ 45 nA, max 250 nA
Icc = typ 0.8 mA, max 2 mA
Input Common Mode Voltage : min 0, max Vcc-1.5V
Voltage Gain at Rl=>2kOhm: min 25V/mV, typ 100V/mV
Common Mode Rejection Ratio : min 65 dB, typ 85 dB
Power Supply Voltage Rejaction Ratio: min 65 dB, typ 100 dB
Output source current at Vcc=15V : min 20 mA, typ 40 mA
  sink current : min 10 mA, typ 20 mA

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MB7053  2 kbit TTL PROM
  I possess a shortform only:

Organization: 512 x 4 bits
Technology: Gold doped TTL P-N junction memory cell
Power consumption: max 735 mW
Access Time max 70 ns
Chip enable Time: typ 22 ns

Pins:
1 : A6
2 : A5
3 : A4
4 : A3
5 : A0
6 : A1
7 : A2
8 : Gnd
9 : O4
10: O3
11: O2
12: O1
13: /CE
14: A8
15: A7
16: Vcc

That's all. The Block Diagram is as usual, the Chip Enable 
activates the output buffers only.

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MB88211 Microcomputer
From the Fujitsu Databook 4-Bit Microcontrollers 1989

CMOS SINGLE-CHIP 4-BIT MICROCOMPUTER WITH A/D CONVERTER

PROGRAMM-MEMORY: 1k x 8bit mask ROM
RAM : 32 x 4bit
I/O: 10 lines + 1 analog input
A/D: 8bit successive Approx.
Clock Generator ( 4MHz)

Instruction set: Subset MB8850-series

Temp.: 0 to 70 C

Package: 20 pin plastic DIP
Pins:
1 : R7
2 : R8
3 : R9
4 : pos.Ref. = Analog-Vcc +5 V DC
5 : neg.Ref. = Analog-Vss Gnd
6 : AN = Analog input to the A/D Converter
7 : R6
8 : X  = Oszillator output
9 : EX = Oszillator input
10: Vss
11: R0
12: R1
13: R2
14: R3
15: R4
16: R5
17: Vss
18: TEST
19: /Reset
20: Vcc

R- Port: two 4-bit and one 2-bit parallel input(non-latched)-/
   output(latched)- ports, or 10 individual lines, depending
   on instructions.
   R7, R8, and R9 have hysteresis inputs.


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MB8852 CMOS 4bit Microcomputer, 2048 x 8 ROM, 128 x 4 RAM

Pins:

1 : EX, Quarz nach Pin 2 oder Eingang von EXternem Oszillator 
2 : X  = Oszillator output    
3 : /RESET
4 : O0
...
10: O6
11: R7, soll wohl O7 heißen, denn R7 ist auf Pin20
12: R0
13: R1
14: Vss
15: R2
....
21: R8
22: R9, /TC (Timer-Counter input)
23: R10, /IRQ (Interrupt Request Input)
24: K0
...
27: K3
28: Vcc

1)Either of X or /STBY is selected using the Mask Option
   Standby scheint dann also nur mit externem Oszillator 
   realisierbar zu sein, nicht mit Quarz.

Der K- Port ist ein non-latched Input Port.
Der O- Port ist ein komplexer latched Output Port.
Der R-Port ist ein komplexer I/O Port.
  ..sehr komplex, wie mir scheint. Selbst die Kurzform in der
   Pin-Tabelle ist zwei Seiten lang. Die genaue Beschreibung 
   hinten im Datenblatt ist noch viel länger.


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MC1010 MECL II series Quad 2-input NOR Gates

Pins:
1 : In A
2 : In A
3 : Out A
4 : In B
5 : In B
6 : Out B
7 : - Vee
8 : Out C
9 : In C
10: In C
11: Out D
12: In D
13: In D
14: + Vcc = Gnd

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MC10116 Triple Line Receiver (ECL 10k- series)

...sensing differential signals over long lines. The bias 
supply Vbb is made available to make the device useful as a 
Schmitt trigger, or in other applications where a stable 
reference voltage is necessary.

Pins (DIL-Gehäuse)
1 : Vcc1
2 : Inv Out A
3 : N.I.Out A
4 : Inv Inp A
5 : N.I.Inp A
6 : Inv Out B
7 : N.I.Out B
8 : Vee
9 : Inv Inp B
10: N.I.Inp B
11: Vbb
12: Inv Inp C
13: N.I.Inp C
14: Inv Out C
15: N.I.Out C
16: Vcc2

Characteristics at 25 grdC.
Power Supply Drain Current Ie : max 21 mA
Input Current I in (H) : max 95 uA dc
  Icbo : max 1 uA dc
Reference Voltage Vbb: min -1.35 V, max -1.23 V
Switching Times:
  Propagation Delay:  min 1 ns, max 2.9 ns
  Rise = Fall Time (20% to 80%): min 1.1 ns, max 3.3 ns

Typischer Gesamtleistungsverbrauch 85 mW ohne Last.

Unbenutzte Eingänge müssen mit Vbb verbunden werden.

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MC1468 Dual +/- 15 V Regulator

Metal Package TO 100

Pins :
1 : Compens (+), 1500 pF to Gnd
2 : Sense (+)
3 : Output (+), Current Sense Resistor to Pin2
4 : + Vcc
5 : - Vee
6 : Output (-), Current Sense resistor to pin7
7 : Sense (-)
8 : Compens (-), 1500 pF to Gnd
9 : Voltage Adjust, 1)
10: Gnd

1) zu einem externen Spannungsteiler zwischen Pin4 und Gnd,
 der dem internen parallelgeschaltet ist, und ihn überbieten
 kann, wenn er niederohmig genug ist.
Der Anschluß Balance Adjust ist nur beim DIL-Gehäuse 
 herausgeführt.

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MC1545L Breitbandverstärker mit umschaltbarem Eingang

Das DIL Gehäuse hat folgende Anschlüsse:
1  : neg. Output
2  : Gate
3  : Non Inv. Input B
4  : Inv.Input B
5  : Non Inv.Input A
6  : Inv.Input A
7  : pos. Output
8  : Vee
9  : Vcc
10 bis 14 : not connected

A und B sind Differenzverstärker, deren Collectoren parallel-
geschaltet und über Emitterfolger zu den Ausgängen geführt 
sind. Die gemeinsamen Emitter der Differenzverstärker- 
Tansistoren sind mit den Collectoren eines dritten Differenz-
verstärkers verbunden, der vom Gate- Eingang gesteuert wird. 
Es ist im Grunde dieselbe Schaltung wie bei Mischer- ICs
und Multiplizierern. Hier ist die Anwendung allerdings für
Breitbandverstärker mit umschaltbarem Eingang.

Maximum Ratings:
Vcc : +12V
Vee : -12V
Input Differential Voltage : +/- 5 V
Load Current : 25 mA
Power Dissipation : 625 mW
Operating Temp. : -55 to 125 grdC.

Characteristics  at Vcc=5V, Vee = -5V, 25 grdC.:
Single ended Voltage Gain: min 16 dB, max 23 dB
Bandwidth : min 40 MHz, typ 50 MHz 
 ( Cout = 15 pF, Leerlauf?, Ab 20 MHz Delle von 4 dB)
Input Impedance at 50 kHz : min 4 kOhm, typ 10 kOhm
Output Impedance at 50 kHz : typ 25 Ohm
Output Differential Voltage Range at Rout = 1 kOhm :
   min 1.5Vpp, typ 2.5Vpp
Input Offset Voltage max 5 mV
Common Mode Rejection Ratio at 50kHz : typ 85 dB
Input Common Mode Voltage Range : typ 2.5V
Gate Low-State Voltage : min 0.4V,typ 0.7V ( A = aus, B = an)
Gate High-State Voltage : typ 1.5V, max 2.2V (A = an, B =aus)
Gate Input Current at Low-State . max 2.5 mA
Gate Input Current at High-State: max 2 uA
Channel Select Time : typ 20 ns
Step Response at e=20mV:
  Turn On Delay : max 10ns
  Rise Time : max 15 ns
  Turn Off Delay : max 10 ns
  Fall Time : max 15 ns
Wideband Input Noise, Rs=50Ohm, 5 Hz to 10 MHz:
  e = typ 25 uV (rms)
DC Power Consumption: max 110 mW

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MC3446 Quad GPIB Transceiver
 Von einem 3- seitigen Motorola Datenblatt.

Pins:
1 : Receiver Output Busbit A 
2 : Bus A
3 : Driver Input A
4 : Enable für A, B, und C
5 : Driver Inp B
6 : Bus B
7 : Rec Out B
8 : Gnd
9 : Rec Out C
10: Bus C
11: Driver In C
12: Enable für D
13: Driver In D
14: Bus D
15: Rec Out D
16: Vcc = +5 V

Der GPIB Meßgerätebus wird hier nicht genauer beschrieben. 
Die Treiber sind mit Offenem Collector an die Busleitung 
angeschlossen. Die Receiver haben ähnliche Schaltschwelle 
wie TTL, aber größere Hysterese.


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MC3447 Oktal Bidirectional Bus Transceiver 
with Termination Networks 

Pins:
1 : S, /R for Transc.0
2 : D0
3 : D1
4 : D2
5 : D3
6 : D4
7 : D5
8 : /S, R for Transc.5 ( Achtung , invertiert)
9 : D6
10: D7
11: S, /R for Transc.6
12: Logic Gnd
13: Bus Gnd
14: S, /R for Transc.7
15: Bus7
16: Bus6
17: S, /R for Transc.1 to 4
18: Bus5
19: Bus4
20: Bus3
21: Bus2
22: Bus1
23: Bus0
24: Vcc

Die Bus Anschlüsse haben interne Widerstände nach Gnd und Vcc.

Interface zwischen TTL (oder MOS) und IEEE Standard 
Instrumentation Bus (488, GPIB ).

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MC4044 Phasen-/ Frequenz- Detektor

Gut, daß Sie vom MC4044 keine Datenblattkopie wünschen. Ich 
stelle nämlich gerade fest, daß ich auch nur eine 
unvollständige Kopie habe. 
Aber die Anschlüsse kann ich Ihnen heraussuchen:

1 : R Eingang für beide Phasen- Frequenz- Detektoren
2 : D1 Ausgang von Detektor 1
3 : V Eingang für beide Ph.-Fr.-Det.
4 : PU = Kathode einer separaten internen Diode
5 : UF = Anode der Diode.
6 : D2 Ausgang von Det.2
7 : Gnd
8 : Collector NPN- Darlington Transistors mit Emitter an Gnd
9 : Basis dieses Darlingtons.
10: DF = Emitterfolger-Ausgang Charge Pump.
11 : PD = TTL-ähnlicher Eingang Charge Pump.
12 : U2 Ausgang von Det2.
14 : U1 Ausgang von Det1.
14 : Vcc

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MC5280 Hybrid IC for Chopper and quarter or half step drive

For the MC5280 I don't possess a full datasheet, only some 
preliminary informations:

This hybrid IC was manufactured by NEC, but developed by 
JANOME, DYNASYN Stepping Motor Drivers.

Hybrid IC for Chopper and quarter or half step drive. It 
maintains an average phase current level through the use of 
a current sensor which turns off whenever the current exceeds
a predetermined high level and turns on whenever the current 
falls below a predetermined low level. It is also possible 
to step the motor 400 or 800 steps per revolution to obtain 
0.9 or 0.45 degree step from 1.8 degree step motor.

Pins :
1 : Gnd (Vcc- side)
2 : sawtooth in, 100mV fast turn on, 50us negative falling ramp
3 : PB0
4 : PA0
5 : PA1
6 : Vcc
7 : 1.5 Ohm,2Watt to Gnd ( I think for the current sensor)
8 : Motor Coil A
9 : 22 uF to Gnd
10: Vb
11: Motor Coil /A
12: Gnd (Vb- side)
13: Gnd (Vcc- side)
14: see pin 2
15: PB1
16: PA2
17: PA3
18: Vcc
19: 1.5 Ohm, 2 Watt to Gnd
20: Motor Coil B
21: 22uF to Gnd
22: Vb
23: Motor Coil /B
24: Gnd (Vb- side)

Half Step PB0 = PB1 = 0:
 Clockwise steps:
PA0  PA1  PA2  PA3  Motor Coils
1    0    1    0    A . B
1    0    0    0      A           1)
1    0    0    1    A . /B
0    0    0    1      /B          1)
0    1    0    1    /A. /B
0    1    0    0      /A          1)
0    1    1    0    /A . B
0    0    1    0       B          1)

1) I think this is for full step 

Quarter Step using PB0 and PB1:

PA0 PA1 PA2 PA3 PB0 PB1  Motor Coils

1   0   1   0   0   0    A . B as for half steps
1   0   1   0   0   1    A . 41% of B
1   0   0   0   0   0      A   as for half steps
1   0   0   1   0   1    A  . 41% of /B
1   0   0   1   0   0    A . /B as for half steps
1   0   0   1   1   0    41% of A . /B
0   0   0   1   0   0      /B  as for half steps
and so on (PB0 reduces A or /A and PB1 reduces B or /B)

PA0, PA1 = 1 . 1 prohibited
PA2, PA3 = 1 . 1 prohibited

From the application:
Vcc = + 5 V
Vb = + 24V or + 30 V
Rated Current 0.65 A 
In the table means A and B current 
  from Pin /A to A and /B to B.
/A and /B current 
  from Pin A to /A and B to /B.

All PA and PB- inputs connected to open collector logic ICs
 or Microcomputer outputs.

Specifications:
Max Vcc = 10 V
Max Vb = 70 V
Max Current = 1 A
T op = -20 grdC to 80 grdC
tstg = -40 to 100 grdC.

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MC5809 UHF power amplifier

From a Datasheet in the databook NEC 1989/1990. It has 
little datas only:

MC5809 : 903 to 905 MHz
MC5809L: 800 to 870 MHz
MC5809M: 860 to 920 MHz
MC5809N: 900 to 960 MHz

Pin 1 : RF Input
3,3,4 : Gnd
Pin 5 : Vcc1
6,7,8 : Gnd
Pin 9 : Vcc2
Pin 10: Gnd
Pin 11: Output

Absolute Maximum Ratings at 25 grdC.:
Vcc = 12 V
Icc = 0.4 A ( Pin 5 + Pin 9 ??? )
Operating Case Temp.: -30 to 80 grdC.
Storage Temp.: -40 to 125 grdC.

Characteristics at 25 grdC., Zin=Zout=50 Ohm :
Power Output at Vcc1=Vcc2=7.2V, f=800 to 960 MHz, Pin=1mW :
   min 120mW, typ 150mW
2nd and 3nd Harmonic : max -30 dB
Input VSWR at f=800 to 960 MHz : max 2.5
Output VSWR at f=800 to 960 MHz : typ 1.5
Load Mismatch at f=905MHz, Vcc1=Vcc2=7.2V, Pout=120mW :
   min 10:1

That's all.
The datasheet has 1 diagram: Output Power vs. Input Power 
( very nonlinear !!) at f=904 MHz, Vcc1=Vcc2=7.2 V:
100mW at 0.3 mW; 150mW at 0.8mW; 170mW at 1.4mW,
185mW (=max) at 2.5mW, 180mW at 3mW.

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MC663 Dual J-K Flip-Flop

The MOTOROLA MC663 is a member of the MC660 High Threshold 
Logic Family.
( Threshold Voltage = 7.5V for Vcc = 15 V )

Pins :
1 : /QA
2 : KA
3 : /RA
4 : /ClA
5 : JA
6 : QA
7 : Gnd
8 : QB
9 : JB
10: /ClB
11: /RB
12: KB
13: /QB
14 Vcc = max 18 V

Output Current max 28 mA
Input Voltage max between -1 V and + 18 V

Input Loading Factor : 
 /R : 2
 /Cl: 1.5
 other: 1
Output Loading Factor for Vcc=15V : 9
Ptot = typ 200 mW
Toggle Frequency : typ 3 MHz

Truth Table for /R = high (/R=low >Q=0,/Q=1):
 T(n)       T(n+1)
J   K   Q    /Q
0   0   Qn   /Qn
1   0   1    0
0   1   0    1
1   1   /Qn  Qn

__________________________________________

Without guaranty! Mistakes are possible. Please ask via email if you find a strange value!

_____________________________________
MC6800 8 bit Microprocessor
   Motorola
From an AMI datasheet S 6800:
Pins :
 1 : Gnd
 2 : /Halt
 3 : Phase1
 4 : /IRQ
 5 : VMA
 6 : /NMI
 7 : BA
 8 : Vcc
 9 : A0
 to
20 : A11
21 : Gnd
22 : A12
 to 
25 : A15
26 : D7
 to
33 : D0
34 : R/W
35 : n.c.
36 : DBE
37 : Phase2
38 : n.c.
39 : TSC
40 : /RESET
____________________________

MC6802 Microprocessor with Clock and RAM 128 x 8bit
    Motorola
    
from an AMI datasheet S6802
Pins:
 3 : MR
35 : Vcc standby
36 : RE
37 : E
38 : XTAL
39 : EXTAL
all other pins are identical to S6800

This datasheet has no detailed declarations for the pins. But 
I think you will find the well known 6800- Family in the 
Internet.

__________________________________________

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_____________________________________
MC890 P dual JK flipflops

Member of the MOTOROLA MRTL Family
from the databook 1968 !!

Pins: plastic DIL package: 
  - for the ceramic flat pac there is an other pinning!
1  : Clear 1 (clocked)
2  : T 1 (negative transition clock)
3  : Set 1 (clocked)
4  : Gnd
5  : Set 2
6  : T 2
7  : Clear 2
8  : /Q 2
9  : Q 2
10 : direct clear 2 ( active high )
11 : Vcc
12 : direct clear 1
13 : Q 1
14 : /Q 1

Toggle Frequency 4 MHz
Loading factor for Q and /Q : 3
  for all inputs = 1 except for T: 2

S  C   after clock
1  1   no change
1  0   Q=1, /Q=0
0  1   Q=0  /Q=1
0  0   both change


__________________________________________

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_____________________________________
MHW1224 Broadband Amplifier

  From the databook Motorola RF Dev.1986:

Pins:
3 : Gnd
4 : deleted (space)
5 : Vcc
6 : deleted (space)
7 : Gnd
8 : Gnd
9 : Output

Maximum Ratings:
RF Input Voltage : +65 dBmV
DC Supply Voltage: 28V
Operating Case Temp.: -20 to 100 grdC.

Characteristics at Vcc=24V, 75 Ohm-system :
Power Gain at 10 MHz: 22 dB
Frequ.Range : 5 to 200 MHz
Gain Flatness: max +/- 0.2 dB
Input/ Output Return Loss: min 18 dB
Cross Modulation Distortion, 12 Channels @ 50 dBmV: typ -67 dB
Composite triple beat Distortion, 26 channels @ 50dBmV :
   max -68.5 dB
Second Order Distortion @ 50dBmV per channel,
   High Split (5-175MHz)CH2,CHA@176.5MHz: max -72 dB
Noise Figure High Split : max 5.5 dB
DC Current . typ 210mA, max 240 mA

__________________________________________

Without guaranty! Mistakes are possible. Please ask via email if you find a strange value!

_____________________________________
MHW4524 Broadband Amplifier

  From the Motorola databook 1986

Pins :
1 : B+
2 : Gnd
3 : RF In
4 : Gnd
5 : Loop
6 : Loop
7 : Gnd
8 : RF Out
9 : Gnd
10: B+

Absolute Maximum Ratings:
RF Voltage Input ( Single Tone ) max +55 dBmV
DC Supply Voltage : max 28 V
Operating Case Temp.: -20 to 90 grdC.
Storage Temp.: -40 to 90 grdC.

Characteristics at Vcc=24V,Tc=35 grdC., 75 Ohm system :
Frequency Range : 40 to 450 MHz
Power Gain at 50 MHz : min 23.3 dB, typ 24 dB, max 24.7 dB
Slope : min 0, max 1.5 dB
Gain Flatness : max +/- 0.3 dB
Return Loss Input/Output : min 18 dB
Second Order Distortion at Vout=50dBmV : IMD max -80 dB
Cross Modulation Distortion at Vout=+46 dBmV , 
   60-Channel FLAT : max -75 dB
Composite Triple Beat at the same conds.:
   at 35 grdC : max -80 dB
   at -20 to 90 grdC.: max -75 dB
Noise Figure at f=450MHz : typ 8 dB, max 8.5 dB
DC Current at Tc=30mA : max 650 mA

FEEDFORWARD AMPLIFIER BLOCK DIAGRAMM:


   Main Loop Delay Line --- Coupler ---- Error Amplifier
         |                      |              |
Power Divider               Resistor ?    Power Combiner--->
         |                      |              |
   Main Amplifier --------- Coupler -- Error Loop Delay Line

I think the exact circuit is very interesting, but it is not
 in the datasheet, sorry.

__________________________________________

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_____________________________________
MHW5382A 450 MHz CATV Amplifier
  From MOTOROLA databook RF DEVICE 1994

Case 714, Style 1 :

RF-Input (left)
Gnd
Gnd 
-
Vcc
-
Gnd
Gnd
RF-Output

Absolute Maximum Ratings:
RF Input Voltage (single Tone) : +55 dBmV
DC Supply Voltage : 28 V
Operating Case Temp.: -20 to 100 grdC.
Storage Temp.: -40 to 100 grdC.

Characteristics at Vcc=24V, Tc=30grdC., 75 Ohm- system:
Frequency Range : 40 to 450 MHz
Power Gain at 50 MHz : min 37 dB, typ 38 dB, max 39,5 dB
  at 450 MHz : min 38 dB, typ 39 dB, max 40 dB
Slope : min 0 dB, typ + 1 dB, max + 2.5 dB
Gain Flatness: typ 0.3 dB, max 0.6 dB
Return Loss Input/Output : min 18 dB
Second Order Intermodulation Distortion 
  at Vout = +46 dBmV per Channel :
   Channel 2, M6, M15 : typ -78 dB
   Channel 2, M13, M22: typ -72 dB, max -64 dB
Cross Modulation Distortion and Composite Triple Beat
  at Vout = +46 dBmV :
   53 Channel FLAT: typ -63 dB
   60 Channel FLAT: typ -61 dB, max -59 dB
DIN Tests:
  DIN 1 , 300 MHz : typ 125 dBuV
  DIN 2 , 400 MHz : typ 124 dBuV
  DIN 3 , 450 MHz : typ 123 dBuV
Noise Figure at 450 MHz : typ 4 dB, max 5 dB
DC Current : typ 310 mA, max 340 mA


__________________________________________

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_____________________________________
MHW559 Wideband Amplifier
I have an 1-page-datasheet of this very old Module in the
 MOTOROLA Databook 1974.

Pins:
1 ( left) = RF Input
2 = Gnd
3 = +V DC
4 = Gnd
5 = RF-Output

Characteristics:
V DC = 24V
DC-Current at Tc=30grdC: I DC = typ 190 mA, max 230 mA
Frequency Range BW = 40 to 300 MHz
Power Gain: Gp = 15.5 to 17.5 dB
Slope S = max 1 dB
Gain Flatness = +/- 0.2 dB
Input Return Loss at Zo=75Ohm: Zin = min 18 dB, typ 20 dB
Output return Loss at Zo=75Ohm: Zout = min 18 dB, typ 20 dB
21-Channel Crossmodulation Distortion at Pout= +50dBmV :
   XMD = max -54 dB
Second Order Intermodulation ( Ch2 + Ch13 = ChReceive )
   IMD = max -64dB
Triple Beat (Ch3+Ch4+ChA=250MHz) TB = typ -78 dB, max -74 dB
Noise Figure at f=300MHz: NF = max 8.5 dB

There are no maximum ratings and no diagrams.

__________________________________________

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_____________________________________
MHW560 Low Distortion Wideband Amplifier Module
I have an 1-page-datasheet of this very old Module in the
 MOTOROLA Databook 1974.

Pins: Bottom View, Flange toward you: 
1 ( left) = RF Input
2 = Gnd
3 = +V DC
4 = Gnd
5 = RF-Output

The datasheet has no maximum ratings, characteristics only:

V DC = 24V
DC-Current at Tc=30grdC: I DC = typ 200mA, max 230mA
Frequency Range BW = 40 to 300 MHz
Power Gain: Gp = 15.5 to 17.5 dB
Slope S = max 1 dB
Gain Flatness = +/- 0.2 dB
Input Return Loss at Zo=75Ohm: Zin = min 16 dB
Output return Loss at Zo=75Ohm: Zout = min 16 dB
Crossmodulation = -51 dB
Intermodulation = -60 dB
Triple Beat = -72 dB
Noise Figure = 8.5 dB


__________________________________________

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_____________________________________
MHW561 Low Distortion Wideband Amplifier Module
  From the MOTOROLA Databook 1974:

Pins: Bottom View, Flange toward you: 
1 ( left) = RF Input
2 = Gnd
3 = +V DC
4 = Gnd
5 = RF-Output

The datasheet has no maximum ratings, characteristics only:
V DC = 24V
DC-Current at Tc=30grdC: I DC = typ 200mA, max 230mA
Frequency Range BW = 40 to 300 MHz
Power Gain: Gp = 15.5 to 17.5 dB
Slope S = max 1 dB
Gain Flatness = +/- 0.2 dB
Input Return Loss at Zo=75Ohm: Zin = min 16 dB
Output return Loss at Zo=75Ohm: Zout = min 16 dB
21-Channel Crossmodulation Distortion at Pout= +50dBmV :
   XMD = max -54 dB
Second Order Intermodulation ( Ch2 + Ch13 = ChReceive)
   IMD = max -66dB
Triple Beat (Ch3+Ch4+ChA=250MHz) TB = typ -78 dB
Noise Figure at f=300MHz: NF = max 12dB

__________________________________________

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_____________________________________
MHW591 Broadband Amplifier
Pins:
1 = RF-Input (left)
2 = Gnd
3 = Gnd
(4 = space)
5 = Vdc
(6 = space)
7 = Gnd
8 = Gnd
9 = RF-Output

Maximum Ratings:
Vdc = max 16V
Input Power = max 3.0 dBm
Operating Case Temp.:-20 to 90 grdC

Characteristics at Vdc=13.6V, Zo=50Ohm:
Frequency Range: 1 to 250 MHz
Power Gain = min 34.5dB, typ 36.5dB, max 38dB
Gain Flatness max +/-1.5 dB
VSWR in/out, f= 1 to 30MHz: typ 1.5:1
    f=30 to 250MHz: typ 2:1
1dB Compression at f=30MHz: min 650mW, typ 800mW
    f= 100MHz: typ 700mW
    f= 250MHz: typ 250mW
Peak Envelope Power (PEP) for IMD3=-30dB, f=30MHz: min 700mW
    f= 100MHz: typ 600mW
    f= 250MHz : typ 300mW
Noise Figure at f=30MHz: typ 3.8, max 5dB
    f=100MHz: typ 3.7dB
    f=250MHz: typ 4.5dB
DC Current: typ300mA, max 340mA

__________________________________________

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_____________________________________
MHW592 Broadband Amplifier

Pins:
1 = RF-Input (left)
2 = Gnd
3 = Gnd
(4 = space)
5 = Vdc
(6 = space)
7 = Gnd
8 = Gnd
9 = RF-Output

Maximum Ratings:
Vdc = max 28V
Input Power = max 5.0 dBm
Operating Case Temp.:-20 to 90 grdC

Characteristics at Vdc=24V, Zo=50Ohm:
Frequency Range: 1 to 250 MHz
Power Gain = min 33.5dB, typ 35dB, max 36.5dB
Gain Flatness max +/-1.0dB
VSWR in/out, f= 1 to 30MHz: typ 1.5:1
    f=30 to 250MHz: typ 2:1
1dB Compression at f=30MHz: min 750mW, typ 900mW
    f= 100MHz: typ 900mW
    f= 250MHz: typ 750mW
Peak Envelope Power (PEP) for IMD3=-30dB, f=30MHz: min 700mW
    f= 100MHz: typ 850mW
    f= 250MHz : typ 600mW
Noise Figure at f=30MHz: typ 3.8, max 5dB
    f=100MHz: typ 3.7dB
    f=250MHz: typ 3.9dB
DC Current: typ300mA, max 340mA

__________________________________________

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_____________________________________
MHW 607-2 VHF Power Amplifier
From the databook MOTOROLA RF Dev 94:

Pins:
1 : Input
2 : Vs1 (+7.5V )
3 : Control Voltage (+7V, typ 250mA)
4 : Vs2 (+7.5V, Is1+Is2=typ 145 mA)
5 : Vs3 (7.5V, typ 1.75 A )
6 : Output

Maximum Ratings:
Vs1, Vs2, Vs3 : 9 V
Control V. : 9 V
RF Input Power : 5 mW
RF Output Power ; 10 W
Operating Temp.: -30 to 100 grdC.

Characteristics:
Frequ.Range: 146 to 174 MHz
Control Voltage : 0 to 7 V
Quiescent Current Is1+Is2 = max 160 mA
Power Gain at Vcont=7V, Pout = 7W : min 38.5 dB
Efficiency at Pin=1mW, Pout=7W : min 40%
Harmonics at ... : 2fo max -40dB, 3fo max -45 dB
Input VSWR at ...: max 2:1
Load Mismatch at Pin=5mW, Pout=8W, VSWR=20:1 : No de-
  gradation in power output.

__________________________________________

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_____________________________________
MHW720 UHF Power Amplifier

  From the Motorola databook RF dev. 1986:
  
Pins:
1 : RF Output (left)
2 : Gnd
3 : Vs2 (2. and 3. Ampl.)

4 : Gnd
5 : Vs1 (1. Amplifier)

6 : Gnd
7 : RF Input

Maximum Ratings :
Vs1, Vs2 = 15.5 V
RF Input Power : 250 mW
RF Output Power at Vs1=Vs2=12.5V : 25 W
Operating Case Temp.: -30 to 100 grdC.

Characteristics at Vs1=Vs2=12.5V, 25 grdC, 50 Ohm :
Frequency Range: A1 -Type : 400 to 440 MHz
                 A2 -Type : 440 to 470 MHz
Input Power fot Pout=20W : max 150 mW
Power Gain at Pout=20W : min 21 dB
Efficiency at Pout=20W : min 35 %
Harmonics : -40 dB
Input Impedance : max 2:1 VSWR
Load Mismatch: No degradation in Pout for VSWR=infinite, 
     Vs1=Vs2=15.5V,Pout=30W
Stability: All spourious outputs more than 60dB below
     desired signal:  Pin=0 to 250mW, Vs1=Vs2= 10 to 15.5V,
     Load VSWR = 4:1 or Source VSWR = 2:1
Quiescent Current = 200 mA

__________________________________________

Without guaranty! Mistakes are possible. Please ask via email if you find a strange value!

_____________________________________
MHW806 UHF Power Amplifier

  From the databook MOTOROLA RF DEVICE 1986:
  
Pins:
1 : RF In
2 : DC Supply 1.st.
3 : DC Supply 2.st.
space
4 : RF Out

Maximum Ratings:
DC Supply Voltage : 16 V
RF Input Power : 400 mW
RF Output Power: 9 W
Operating Case Temperature: -40 ... 100 grdC

Characteristics:
Frequency Range at Vs=12.5V:
MHW806-1 : 820 ... 850 MHz
  -2 : 806 ... 870 MHz
  -3 : 890 ... 915 MHz
  -4 : 870 ... 960 MHz !
Input Power for Pout=6W , Vs=12.5V:
  -1 : typ 200, max 250 mW
  -2 : typ 200, max 250 mW
  -3 : typ 300, max 350 mW
  -4 : typ 300, max 350 mW
Power Gain at Pout=6W, Vs=12.5V:
  -1 : min 13.8, typ 14.7 dB
  -2 : min 13.8, typ 14.7 dB
  -3 : min 12.3, typ 13 dB
  -4 : min 12.3, typ 13 dB
Efficiency Vs=12.5V: min 30%, typ 38%
Harmonic Output : -45 dB to Reference Pout=6W
Input VSWR (50 Ohm- Reference) : 2 : 1
Power Degradation at Vs=12.5V,Pout=6W for -30 to 80grdC :
    1.2 dB   (Reference = 25 grdC)
Load Mismatch Stress:
    No degradation in Power Output for Vs=16V,Pout=7.5W,
    VSWR=30:1, all phase angles
Stability:
    All spurious outputs >= 70 dB below the desired output 
    signal level for  Vs = 10 to 16V, Pout = 0 to 7.5W, 
    Load VSWR = 4:1
Quiescent Current: max 125 mA

__________________________________________

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_____________________________________
MK4116P 16384 x 1 bit dynamic RAM

von einem MOSTEK Datenblatt

Pins:
1 : Vbb = -5V
2 : Din
3 : /WRITE
4 : /RAS
5 : A0
6 : A2
7 : A1
8 : Vdd = +12V
9 : Vcc = +5V
10: A5
11: A4
12: A3
13: A6
14: Dout
15: /CAS
16: Vss = Gnd

__________________________________________

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_____________________________________
MK50395 Six Decade Couter/ Display Decoder

Pins:
 1 : Vss
 2 : /SET (Scan counter to MSD)
 3 : /LZB (leading zeros blanking)
 4 : a segment
...
10 : g segment
11 : A BCD output (LSB)
12 : B
13 : C
14 : D
15 : STORE
16 : Cd Couter BCD Input (MSB)
17 : Cc
18 : Cb
19 : Ca
20 : CLEAR
21 : SCAN ( Capacitor for Scan oszillator )
22 : Vdd
23 : EQUAL output
24 : D1 Digit Strobe Output (LSD)
....
29 : D6
30 : LOAD REGISTER
31 : LOAD COUNTER
32 : Rd Register BCD Inputs (MSB)
33 : Rc
34 : Rb
35 : Ra
36 : COUNT (Zählereingangsimpulse)
37 : COUNT INHIBIT
38 : CARRY output
39 : ZERO output
40 : UP/DOWN


__________________________________________

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_____________________________________
ML4817
 From an ADVANCE INFORMATION only in the ML databook 1991:

Pins :
1 : Inv Input to the Error Amp.
2 : Noninv. Inp. to the Error Amp.
3 : Error Amp. Output = inv Input of PWM Comp.
4 : Clock Output (perhaps Input too)
5 : Irc Output R(C) of Osc.
6 : C(T) Osc.
7 : R(D) Osc.
8 : Soft Start, internal Switch to Gnd     1)
9 : I(LIM)/Shutdown  noninv Inp. of the Comparator   2)
10: RAMP = Noninv Input of PWM Comp. minus 1.25V
11: Gnd
12: Power Output
13: Power Gnd
14: Vcc
15: 5.1 V Vref
16: RC(Reset)       3)

1) at Reset or Under Voltage

2) The comparator has 1.4V at the inverted Input.

3) The Output of the comparator near pin9 sets a flipflop. The
Q-Output of the flipflop switches on a current to the RC at 
Pin 16. The voltage at Pin16 is compared with 1.1V or 2.3V 
(trigger levels). The Output of the Reset Comparator is ORed 
with the ouput of the Undervoltage Lockout and to the Base 
of the NPN Transister (Collector = Pin8).

Compared with the well known UC1823 Family I find differences 
for Pin11 because the UC1823 has a separate I(lim) Comparator.
Futher differences for Pin7, Pin 10 until 14 for pinning only.
Internal it seems to have the same functions.

In the Text for the ML4817 features I find little datas:

Fabricated on a 40 V bipolar process.
Switching Frequencies to 1 MHz.
High Current (2A peak) Totem Pole Output.
Under Voltage Lockout circuit with 3.6 V hysteresis.

__________________________________________

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_____________________________________
MM4204/5204 512 x 8 UV EPROM

 I have a copy of a copy only, not suitable for a scan.
I try to identify the most important values:

Silicon Gate Technology to achieve bipolar compatibility.
Programming by applying a -50 V pulse.
TriState controled by /CS.

Pins :
 1 : Vbb
 2 : Power Saver
 3 : /CS
 4 : PROGRAM
 5 : A0
 6 : A1
 7 : A2
 8 : A3
 9 : A4
10 : A5
11 : A6
12 : Vss
13 : A7 ? (copy partial destroid)
14 : A8 ?
15 : D0 ?
16 : D1 ?
17 : D2 ?
18 : D3 ?
19 : D4
20 : D5
21 : D6
22 : D7
23 : Vdd
24 : VLL ?

Absolute Maximum Ratings :
All Input or Output Voltages with Respect to Vbb
   except during programming :  +0.3 V to -20 V
Power Dissipation : 750 mW
Operating Temp.: MM4204 : -55 to 85 grdC
                 MM5204 :   0 to 70 grdC.
T stg = -65 to 125 grdC.

Characteristics
at VLL = 0 V, Vbb = PROGRAM = Vss = 5V, Vdd = -12V
(Tolerances MM4204:+/-10%, MM5204: +/-5%) :
V IL : min Vss-14 V, max Vss-4.2 V
V IH : min Vss-1.5V, max Vss+0.3 V
V OL at I OL =1.6mA: max 0.4 V
V OH at I OH =0.8mA: min 2.4 V
Power Supply Current at /CS=V IH
  Idd at Power Saver = V IL : max 50 mA
  Idd at Power Saver = V IH : max 10 mA
  Iss at Power Saver = V IL : max 52 mA
  Iss at Power Saver = V IH : max 12 mA
Access Time : typ 0.75 us, max 1 us (MM4204 max 1.25 us)
Power Saver Setup Time: max 2 us
Chip Select Delay : max 500 ns (MM4204 max 600 ns)
Data Hold Time:min 30 ns, typ 50 ns
Chip Deselect Time = Power Saver Deselect 
   Time : min 30 ns, typ 300 ns, max 600 ns

The datasheet has no declarations for the progamming rules 

__________________________________________

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_____________________________________
MM5318 TV digital clock

From a National Semiconductor 3-page datasheet:

Pins:
 1 : Vdd = 0 V
 2 : /BCD8 Multiplexed BCD Outputs (negative logic)
 3 : /BCD4
 4 : /BCD2
 5 : /BCD1
 6 : a         \
 7 : b         |
 8 : c          \
 9 : d           1)
10 : e          /
11 : f         |
12 : g         /
13 : 12/24 hour select
14 : 50/60 Hz select
15 : Vss = 14 V
16 : HOLD for the prescale counter
17 : SLOW SET (for the seconds counter)
18 : FAST SET (for the minute counter)
19 : 50/60 Hz input
20 : S10 Digit Enable Outputs (Sec.)
21 : S1
22 : H10          (Hour)
23 : H1
24 : M10          (Minute)
25 : M1
26 : DX Digit select Lines inputs  2)
27 : DY
28 : DZ

  1) multiplexed 7 segment outputs, open drain from +VSS via 
     internal P-channel MOSFETs.
  2) from MM5841 TV display on screen controller.

Digit                Digit Displayed
Select
Lines        S1   S10    *   M1   M10   *   H1   H10

DX            1     0    0    1     1   0    0    1
DY            1     1    0    0     0   0    1    1
DZ            0     0    0    0     1   1    1    1    
* = Output blanked


__________________________________________

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_____________________________________
MM5832 + MM5833 chromatic frequency generator

Zu diesen Orgel- ICs habe ich ein Datenblatt von NATIONAL
SEMICONDUCTOR mit nur 3 Seiten. Aber das Wichtigste steht wohl
drin. Anscheinend braucht man immer beide ICs in Kombination, 
um alle 13 Halbtöne einer Oktave zu erzeugen.

Pins MM5832:
1  : Gnd
2  : Trigger = Takt 2,00024MHz
3  : not connected
4  : Reset ( an Gnd)
5  : Vgg = -27V, typ 3,5 mA
6  : Vdd = -14V, typ 34 mA
7  : Vss = -10V, typ 25 mA (no output loads)
8  : Output G8 = 6270,34 Hz
9  : Output G#8= 6645,32 Hz
10 : Output A8 = 7043,10 Hz
11 : Output A#8= 7463,58 Hz
12 : Output B8 = 7906,09 Hz
13 : Output C9 = 8369,21 Hz
14 : Output C8 = 4184,61 Hz

Pins MM5833:
 1 bis 7 wie oben,
8  : Output C#8= 4435,12 Hz
9  : Output D8 = 4695,40 Hz
10 : Output D#8= 4975,72 Hz
11 : Output E8 = 5277,68 Hz
12 : Output F8 = 5587,26 Hz
13 : Output F#8= 5917,87 Hz
14 : not connected

Diese ICs sind in einer auch damals unüblichen MOS-Technologie 
hergestellt, die drei verschiedene negative 
Versorgungsspannungen benötigt:

Absolute Maximum Ratings:
Clock Generator Voltage Vgg : max -33V
Logic Supply Voltage Vdd : max -25V
Buffer Supply Voltage Vbb : max -18V
Trigger Input Voltage : max -18V
Power Dissipation max 800mW
Temp: 0 to 70 grdC

Characteristics:
Buffer Outputs loaded 20kOhm to Gnd and 20kOhm to Vbb: 
  High Level: -2V to 0 V
  Low Level: -Vbb to -8 V
Ebenso auch Takteingang

Im Applikationsschaltbild sind alle Ausgänge mit je einem 
MM5824 an Pin 6 verbunden. Diese Teiler- ICs liefern dann die 
Oktaven Nr 2 bis 7.

Wenn Sie eine nostalgische Orgel reaktivieren möchten, kann 
ich Ihnen nur wünschen, daß diese ICs noch in Ordnung sind. 
Denn Ersatzteile zu bekommen, dürfte selbst über das Internet 
schwierig sein. Damals waren die Plastikgehäuse noch nicht 
besonders zuverlässig. Es gab Fälle, da sind alle ICs eines 
Produktionsjahrgangs nach 8 bis 10 Jahren ausgefallen, egal 
ob sie eingebaut und in Betrieb waren, oder auf dem 
Ersatzteillager herumgelegen haben. Und diese MM- Typen von
NS wurden meines Wissens ca. 1975 zuletzt produziert.

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MMI53511024 x 4bit PROM

Dazu habe ich leider kein vollständiges Datenblatt sondern nur
eine Kurzinformation aus der Anfangszeit. In späteren 
Datenbüchern von MMI war er dann wohl schon wieder 
herausgefallen.

1024 x 4bit PROM ,3-State, nichrome fusible link,
 (kompatibel zu ROM 5250 )

Anlieferungszustand ist mit allen Ausgängen H,
  programmiert wird nach L.

Pins:
1 : Address A9
2 : A6
3 : A5
4 : A4
5 : A3
6 : A0
7 : A1
8 : A2
9 : Gnd
10: Output O4
11: O3
12: O2
13: O1
14: /E1 Enable und Programm   1)
15: A8
16: A7
17: E2     1)
18: Vcc

1)To enable the device /E1 must be low and E2 must be high

Absolute Maximum Ratings:
Vcc = 0.5 to 7 V
Input Voltage: 1 to 5.5 V
Output Current : 100 mA
Input Current : -20 to 5 mA
Pin6 Voltage during Vol Checks : 13 V
Program Pin Voltage (Pin14) during programming : 35 V
Output Voltage during programming : 27 V
Programming Duty Cycle : max 25 %
Storage Temp.: -65 to 150 grdC.

Characteristics:
Input Load Current: typ -60 uA, max -250 uA
Versorgungsstrom : typ 105 mA, max 175 mA

folgende Werte für Typ 6351, 0 bis 75grdC:
  Address Access Time : min 10ns, max 60ns
  Enable Access Time : min 5 ns, max 30 ns
  Enable Recovery Time : min 5ns, max 30ns
  Chip Enable to Low Impedance Delay : min 5 ns
  ...to high Imped. : max 30 ns
Mittlere Programmierzeit 1 ms/bit

Das ist leider schon alles. Das interessanteste ist der Preis
anno 1975: 212,40 DM das Stück!

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MMI 6301-1 256 x 4bit PROM

Three-State NiCr fusible links Schottky PROM

Pins:
1 : A6
2 : A5
3 : A4
4 : A3
5 : A0
6 : A1
7 : A2
8 : Gnd
9 : O4
10: O3
11: O2
12: O1
13: P, /E1
14: /E2
15: A7
16: Vcc

For Programming apply min 27V, max 33V to the Program Pin, 
then apply min 20V, max 26V to the Output to be programmed. 
Pulse width of Vout : min 10us, max 40us

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MMI6336

Pins:
1 : A7
2 : A6
3 : A5
4 : A4
5 : A3
6 : A2
7 : A1
8 : A0
9 : O1
10: O2
11: O3
12: Gnd
13: O4
14: O5
15: O6
16: O7
17: O8
18: E4
19: E3
20: P, /E2
21: /E1
22: (n.c.)
23: (n.c.)
24: Vcc

Programming: 
Adressen anlegen, dann Vcc auf 5.5V, dann 27...33V an P,
dann (nach 0...20us) 20...26V an Output pin für 10 ... 40us,
dann (nach 0...1us) auch P wieder auf 0.

Das für alle Output Pins einzeln wiederholen!


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MMI6389 2048 x 4 bit bipolar PROM (NiCr-Fuses)

aus einem MMI-Datenbuch von 1982:

Three-state Outputs :
Output short-circuit pulse current, Vo=0V, Vcc=5V :
   max -90mA, min -20mA.
   ( Mit diesen alten Stromfressern konnte man noch 
   Leistungstransistoren direkt ansteuern!)
Supply Current max 155 mA.
Eingänge TTL-kompatibel.
Adress Access Time max 55 ns
Enable Access and Recovery Time max 30 ns

Pins:
1  : A6
2  : A5
3  : A4
4  : A3
5  : A0
6  : A1
7  : A2
8  : A10
9  : Gnd
10 : P = /E
11 : Q4
12 : Q3
13 : Q2
14 : Q1
15 : A9
16 : A8
17 : A7
18 : Vcc

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MP7521 12 bit Monolithic Muliplying D/A Converter

From a 3- page Micro Power Systems datasheet:

Replaces AD7521
Pin compatible with MP7621
Recommended for new designs: MP7623

Comparison with the AD7521 datasheet:

Nearly all the same, even the Suffixes for the 
  Temperature Classes.

Differences         :     MP     AD

Nonlinearity Tempco :   0.2 ppm  2 ppm
Gain Error Tempco   :   2 ppm   10 ppm
Capacitances, typical
  All Inputs high
     I out 1        :  52 pF    120 pF
     I out 2        :  13 pF     37 pF
  All inputs low
     I out 1        :  26 pF     37 pF
     I out 2        :  45 pF    120 pF

The typical performace curves are identical.

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MPC508A Single Ended 8 Channel CMOS Analog Multiplexer

 Aus dem Burr-Brown Datenbuch Data Conv.95:
 
Pins:
1  : A0  (für Kanal 1 : A0 = A1 = A2 = Low)
2  : Enable ( Low: alle Kanäle aus)
3  : -Vsupply
4  : In1
5  : In2
6  : In3
7  : In4
8  : Out
9  : In8
10 : In7
11 : In6
12 : In5
13 : +Vsupply
14 : Gnd
15 : A2
16 : A1

Single Ended ist hier im Gegensatz zu Differential oder 
Stereo zu interpretieren, nicht bezüglich der Betriebsspannung.
Das IC ist für +15V und -15V Versorgung, und das ist dann auch 
der Bereich für Eingangs- und Ausgangspegel.

Pegel der Digitalsignale: Low unter 0,8V, High über 4V.
Power Dissipation typ 7.5 mW

Absolute Maximum Ratings:
V+ to Gnd : 22V
V- to Gnd : 25V
V+ to V-  : 44V
Digital Input Overvoltage to V+ or V- : 4 V or max 20mA, 
  whichever occurs first.
Analog Input Overvoltage to V+ or V- : 20V
Continuous Current S or D : 20mA
Peak, pulsed 1ms : 40 mA
Pd = 1.28W
Temp.: -40 to 85 grdC.

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MS88128 128k x 8 CMOS Static RAM Modul

Pins:
1 : NC
2 : A16
3 : A14
4 : A12
5 : A7
6 : A6
7 : A5
8 : A4
9 : A3
10: A2
11: A1
12: A0
13: DQ0
14: DQ1
15: DQ2
16: Gnd
17: DQ3
18: DQ4
19: DQ5
20: DQ6
21: DQ7
22: /E = Chip Enable
23: A10
24: /G = Output Enable
25: A11
26: A9
27: A8
28: A13
29: /W
30: NC
31: A15
32: Vcc = +5V

TTL-compatible, Three state outputs

Operating Power Supply Current : typ 50 mA, max 95 mA
Standby for /E > Vih           : typ 2 mA, max 15 mA
Power Down for /E > Vcc-0.2V   : typ 50 uA, max 500 uA  1)
Vcc for Data Retention at /E = /G > Vcc-0.2V : min 2 V  1)
   Current at data retention   : typ 20 uA, max 100 uA  1)

1) Vin < 0.2V or > Vcc-0.2V

Im vorläufigen Datenblatt gibt es Typen für Read Access Time
 100ns und 120 ns, 70ns ist angekündigt.

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MSM514400 1 048 576 Word x 4 bit dynamic RAM
  OKI

Fast Page Mode Type

Der Typ ...D kommt in meinem Datenblatt nicht vor. Deshalb 
nehme ich das Pinning vom Typ ...RS (20pin Dual In Line) 
und vom ZIP- Typ :

DIL         ZIP

1 : D1      6
2 : D2      7
3 : /WE     8
4 : /RAS    9
5 : A9     10
6 : A0     11
7 : A1     12
8 : A2     13
9 : A3     14
10: Vcc    15
11: A4     16
12: A5     17
13: A6     18
14: A7     19
15: A8     20
16: /OE     1
17: /CAS    2
18: D3      3
19: D4      4
20: Vss     5  

Das SOJ-Gehäuse hat dieselbe Reihenfolge.
Beim ZIP-Gehäuse gelten die rechts hinzugeschriebenen 
Pinnummern.

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MSM5219BGS 48 Dot Static LCD Driver
 48bit Shift Register/Latch/Driver

Pins :
1 : SEG33
...
16: SEG48
  (corner)
17: LOAD
18: CLOCK1 for shift register
19: DATA IN
20: DATA OUT 32
21: DATA OUT 48
22: SELF/External ( SELF= oscillator with 1/8 division)
23: Vdd
24: OSC ( for LCD, external R to Vcc, C to Gnd)
25: Gnd
26: ALL ON (priority)
27: BLANK (subpriority)
28: COM (common side of LCD)
29: SEG 1
30: SEG 2
  (corner)
31: SEG 3
...
40: SEG18
  (corner)
41: SEG19
....
60: SEG32

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MSM5807 PLL frequency synthesizer

1976 hat OKI noch keine englischen Datenblätter gehabt. Wir 
hatten das Glück, daß uns ein Kontaktmann in Japan das 
Datenblatt vom MSM5807 übersetzt hat. Ich versuche, das 
handschriftliche Blatt zu entziffern:

Pins:
1  : P5  Programmiereingang
2  : P6
3  : P7
4  : P8
5  : Select Low: 5kHz-Raster, High: 10kHz-Raster  1)
6  : Quarz nach 7, + C nach Gnd
7  : Quarz + C nach Gnd
8  : Gnd
9  : Ausgang zum Loop-Filter
10 : Lock-Detector Ausgang
11 : Eingang Einstellteiler
12 : P1
13 : P2
14 : P3
15 : P4
16 : Vdd= 5V

1) bei Quarzfrequenz = 5,12 MHz

Die Programmiereingänge haben (unüblich!) interne 10kOhm- 
Widerstände nach Gnd. Der Taktoszillator eignet sich für
max. 10,24 MHz für 10kHz/20kHz- Raster. Es folgt ein 10-
stufiger Festteiler.

Die maximale Einstellteilerfrequenz ist 5 MHz. Der 
programmierbare 8 bit- Teiler kann von 3 bis 255 eingestellt 
werden. Hier ist im Text ein Ausgang Namens N Count Out 
erwähnt, den es im Pinning aber nicht gibt. Das läßt darauf 
schließen, daß der Text allgemein für die ganze Familie 
verfasst worden ist.
Der 5807 hat einen Tristate MOS-Ausgang, der also nur 
positive oder negative Stromimpulse liefert, wenn es eine 
Phasenabweichung gibt. Vereinfachend für den Bastler ist es
jedenfalls, daß die Programmierung damals immer parallel 
erfolgte, üblicherweise von Programmierschaltern, die direkt 
den Binärcode lieferten.

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MT42C4256 256K x 4 DRAM with 512 x 4 SAM

Das Datenblatt von MICRON hat 36 Seiten.

Pins:
SOJ         ZIP
1  : SC       8
2  : SDQ1     9
3  : SDQ2     10
4  : /TR, /OE 11
5  : D1       12
6  : D2       13
7  : /ME,/WE  14
8  : NC       15
9  : /RAS     16
10 : A8       17
11 : A6       18
12 : A5       19
13 : A4       20
14 : Vcc      21

15 : A7       22
16 : A3       23
17 : A2       24
18 : A1       25
19 : A0       26
20 : QSF      27
21 : /CAS     28
22 : DSF      1
23 : D3       2
24 : D4       3
25 : /SE      4
26 : SDQ3     5
27 : SDQ4     6
28 : Vss      7

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MUX1600 -I 18- Channel Analog Multiplexer

From a GENERAL INSTRUMENT datasheet:

N-channel-Technology
5-bit Latch-register with Address Strobe Input
5-bit to 18 Decoder and 18 Switches with common output.

Case 28 Lead Dual In Line.
Pins:
1  : Gnd
2  : /Chip Select
3  : Address Strobe
4  : A0
5  : A1
6  : A2
7  : A3
8  : A4
9  : +Vdd (+12V)
10 : In1
11 : In2
12 : In3
13 : In4
14 : In5
15 : In6
16 : In7
17 : In8
18 : In9
19 : In10
20 : In11
21 : In12
22 : In13
23 : In14
24 : In15
25 : In16
26 : In17
27 : In18
28 : Analog Output

Maximum Ratings:
Vdd and all other input/output : to Gnd -0.3 to +18V .
Operating Temp: 0 to 70 GrdC .

Standard Conditions Vdd = 12V +-5%
Power Supply Current max 8mA .
Input Low Voltage : -0.5 ...+0.8 V .
Input High Voltage : min 2.2V .
Analog Input Voltage : 0 to 6V .
Channel ON Resistance : max 600 Ohm .
Source to Drain Capacitance max 5pF .
Analog Input Capacitance : max 5pF .
Analog Output Capacitance : max 20pF .
Each Channel Leakage (Vin - Vout = 6V) : max 5nA .
Leakage Vdd to Output( Vdd -Vout = 17V) : max 10nA .
Substrate Leakage (Vout = 6V) : max 410nA .
Total Leakage (18 Inputs + L.toVdd + SubstLeak) : max 500nA 

Address Strobe Delay : min 50ns after Address Stabilisation 
Address Strobe Pulse : min 200ns 
Address Hold Time : min 50ns after the end of the
    Address Strobe Pulse 
Analog Switch Stabilisation typ 3us after the End of the
    Address Strobe Pulse

__________________________________________

Without guaranty! Mistakes are possible. Please ask via email if you find a strange value!

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MWA5121 Wideband Hybrid Amplifier

From a 4-page datasheet in the MOTOROLA databook 1986:

Pins :
1 : Output
7 : +Vcc
11: Input
all others : Gnd

Absolute Maximum Ratings :
Vcc : 24 V
Vin = Vout : +/- 25 V DC
Icc : 50 mA
RF Input Voltage : 0.5 V
Pt = 1.2 W
Top = -30 to 65 grdC.
Tstg = -30 to 85 grdC.

Recommended:
Vcc = 18 to 22 V
Source and Load 50 to 75 Ohm
Top = -10 to 40 grdC.

Characteristics :
Icc : min 35 mA, typ 40 mA, max 45 mA
Gain at 100 MHz : min 25 dB, typ 27 dB, max 30 dB
Gain Flatness f=30 to 890 MHz : typ 2 dB, max 5 dB
Input VSWR f=30to890MHz, Zs=Zl=50Ohm: typ 2.1, max 3
Output VSWR ..... : typ 1.5, max 3
Isolation .... : typ 50 dB
Noise Figure 30 to 300 MHz : typ 3.5dB, max 7 dB
    300 to 890 MHz : typ 4 dB, max 8 dB
    From a diagram : The best NF is typ 3 dB for 500 MHz

From a diagram: The maximum available output power is 8 dBm 
    for Vcc=24V, 1 dB Gain Compression.

From a diagram: Second Order Intermodulation Distortion 
    for f1=55.25MHz, f2=211.25 MHz, Vce=20V, Dist=f1+f2: 
       -60 dB for Pout=-20 dBm, -37 dB for -5 dBm.
Third Order: 199.25MHz, 211.25MHz, Dist = 2 f2 - f1 :
       -80dB for -20dBm, -53 dBm for -5 dBm.

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_____________________________________
MX12 Class C rugged RF power Module

Pins von links nach rechts, wenn die Beinchen nach 
unten zeigen:
1 : RF Out
2 : Gnd
3 : +B

4 : Gnd
5 : Gain
6 : Gnd
7 : RF In

TRW scheint allerdings bei RF In, also rechts, mit Pin 1 
zu zählen zu beginnen.

Absolute Maximum Ratings:
Supply Voltage : 16 V
Total Current : 4 A
Power Input : 250 mW
Power Output : 14 W
Tstg = Top = -30 ... 100 grdC.

Characteristics:
Frequency Ranges :
   400 - 430 MHz / 430 - 470 MHz / 470 - 512 MHz
Supply Voltage : 12.5 V
Power Gain at P in = 150 mW : 12 W  
  ( sollte wohl Output Power heißen )
Efficiency at rated power : 35 %
Harmonic Content : min -30 dB  
  ( sollte wohl maximal sein, oder minimale Dämpfung)
Load VSWR at 14 V, 14 W, low frequency : unendlich zu 1
Power derating at -30 to 70 grdC.: max 2 dB 
Stability at any frequency, 0 - 16 V DC, 0 - 250mW, max 14 W
  Bei anderen Typen war mit der variablen Spannung nur die 
  Vorstufe gemeint, also Anschluss Gain...

Input Impedance : 50 Ohm
Return Loss : max - 10 dB
Output Impedance : 50 Ohm
Gain Control Range at ??? : min 10 dB

typ 4 grdC./W JF , ich denke Junction to Flange, 
Wärmewiderstand.

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