OUTLINE TECHNICAL SPECIFICATION 1.1 The Microvision Fl at Screen Pocket TV (FTV) is a portable Monochrome Television receiver displaying a 50mm 12 E diagonal picture size operating in the UHF waveband (and in the VHF/UHF band on Models 2A USA and EURO versions) The receiver incorporates a simple telescopic aerial and automatically selects response to 625 or 525 line UHF transmission standards on issue 10 and 12 land VHF'UHF on issue 2Ai Controls are provided for Volume/On-off and continuous tuning, and Band switching is provided on issue 2A Sound output is through an internal loudspeaker or alternatively by personal earphone with automatic loudspeaker cut-out. Power is supplied from a flat 6V battery giving approximately 15 hours normal life, 240v, 220v and 120v Mains power supply units are also available, Dimensions: 140mm x 88mm x 32mm with aerial folded (5.5" x 3.5" x 1.25") Weight: 280g (1Ooz ) excluding battery Power supply: 4.7V to 6.5V DC Receiving frequencies: UHF 470MHz to 855MHz VHF 55MHz to 103MHz, and VHF 138MHz to 247MHz (2A Models) Receiving standards: 525 and 625 lines (All Models) 6.0MHz sound (Issue 12), System 1 4.5MHz sound (Issue 2A} USA, System M 5.5MHz sound (Issue 2A) EURO, System B, G and H Operating temperature range: 0 to 40 degrees C (32 to 104 degrees F) Storage temperature range: -20 to 40 degrees C 2.1 A simplified block diagram of the receiver is given in Figure 1. Four main elements are shown namely the flat electrostatic tube, vari-cap tuner, custom LSI circuit and power Converter, also three discrete amplifiers: one each for the video, frame and sound waveforms. The circuit is completed by the line integrators and a number of present potentiometers used for setting up circuit parameters during manufacture and after repair There are five potentiometers for adjusting the picture size position and height, and two others for optimising the performance of the sound and line Phase locker; loops implemented within the IC. 2.2 Tube Design 2.2.1 The Microvision flat screen hike is Comparable with a CRO tube, employing electrostatic beam deflection techniques rather than magnetic beam deflection found in conventional television tubes. The other, and perhaps most significant difference between flat and conventional tube design, is the need to 'bend the electron beam to produce a linear picture viewed from the gun side of the phosphor (not through it) on a screen in a plane parallel with that of the gun (rather than normal to it). This 'bending' is achieved by shaping the scanning waveforms to counter the non-linear tube geometry and by generating a voltage gradient between the viewing screen and a repeller coating on the front glass, which encourages the electrons to strike the phosphor almost vertical. Without the repeller the electrons would strike the screen at an oblique angle making focusing extremely difficult. 2.2.2 EHT voltages for the tube, ranging from 460V to 2300V d c, are generated by the power converter. The electron beam is sourced by a directly-heated cathode The neater supply is from an isolated a.c. winding in the power converter and rides on top of the line-blanking waveform, The beam is modulated by video injected into the grid and accelerated by three anodes A1 to A3. A2 is the focusing anode fed from the frame supply via potentiometer RV6. 2.2.3 From A3 the beam passes between line and frame deflection plates, each pair fed with complementary drive waveforms which cause the beam to be deflected up and down, left and right across the screen. The beam finally strikes the phosphor screen deflected downwards by the repeller field. 2.2.4 Picture position is controlled by introducing d.c. offset voltages on the line and frame plates fed from the repeller supply via two potentiometers RV3 (horizontal) and RV4 (vertical). Picture height and width are functions of the frame amplifier and line integrator set by RV5 and RV7 respectively; contrast and brilliance are both fixed. 2.2.5 Two further electrodes affecting picture quality are the interplate shield (pin 8) and the guard band (pin 14). These control the astigmatism of the picture (not adjustable) and prevent edge effects around the screen caused by charging up of the glass. 2.3 Tuner 2.3.1 The UHF tuner may be regarded as a black box for repair purposes. It operates on the 'vari-cap' principle, receiving a variable voltage from the TUNE potentiometer RV1. The tuning voltage is a proportion of a 28V regulated supply derived within the power converter, and is relative to the +3V tuner supply from the IC. The IF signal is centred at 230MHz (280MHz on 2A) and is routed to an untuned IF amplifier incorporated within the IC. 2.4 Video, Sync and Sound Separation 2.4.1 The video, sync and sound separation circuits are incorporated in the IC. There are minimal external components, those illustrated being concerned mainly with the line phase locked loop and the sound. These include two potentiometers, which adjust the free running frequency of the two VCOs, and a low pass RC filter network in the feedback circuit. 2.4.2 The receiver automatically adjusts the line and sound local oscillator frequencies to cater for 625 and 525 line transmission standards. The numbers of lines in a frame are counted and, having determined the standard, the corresponding frequencies are selected. In this application, the sound IF chosen is 250kHz. On the UK 625 standard, sound is received from the video detector 6MHz above the picture carrier. This is then mixed with the local oscillator operating at 5.75MHz to obtain the IF sound frequency. European 625 line sound is at 5.5MHz, also producing 250kHz sound IF. In the 525 line system, the sound carrier is at 4.5MHz and so the local oscillator must operate at 4.75MHz. 2.4.3 Sound. After detection the audio is applied to an external preamplifier and then returned to the IC power stage. Audio finally outputs to the internal loudspeaker or via the socket to the external earphone. The maximum power output is 140mW into 32 ohms nominal, the volume being controlled at the preamplifier stage using RV2. 2.4.4 Video. The picture video is detected within the IC and delivered to the tube grid after external amplification. A filtered version of the signal is also returned to the SYNC SEP input (pin 20) biased from the 31V tuning supply by R49. The separator derives line and frame sync for the line phase locked loop and the field counter referred to earlier. 2.4.5 Line Scan. The line scan waveforms delivered to the tube are derived by a pair of line integrators external to the IC. The integrators are in turn driven by complementary line drive outputs from the power converter and the line correction output from the IC. The former are derived from the converter drive waveform at IC pin 6 and charge the integrators during the line flyback time. The integrator discharge time is a function of the line correction waveform and RV7 While RV7 controls the overall discharge rate (i.e. the picture width) the correction waveform increases the discharge rate as the line progresses thus compensating for the non-linear tube characteristics. 2.4.6 Frame Blanking. Frame blanking is a function of the line integrators. The integrators are charged in the normal way but are prevented from discharging until frame flyback is completed. In this way the line scan is kept at the left side of the tube, just outside the picture area. 2.4.7 Frame Scan. Complementary frame scan waveforms are derived entirely within the IC and are applied to the tube after external amplification. Because the frame sensitivity of the tube is non-linear (i.e. greater at the beginning of the line and less at the end) the application of linear frame scan waveforms would result in a trapezoidal picture narrowing at the gun end. To correct this irregularity the IC multiplies the line scan waveform into the frame scan in such a way that the frame scan is decreased at the start or a line and increased towards the end. Picture height is controlled independently using RV5. 2.5 Power Supply 2 5 1 The power converter derives the heater, line blanking and EHT supplies for the tube and delivers 18V and 31V supplies to the video amplifier and the tuning potentiometer, RV1 respectively. 2.5.2 The primary power source is a slide-in 6V lithium battery or the output of the main adapter at 5.9V. It is applied to the primaries of two variably coupled transformers and switched on and off by the converter drive waveform from IC pin 6. Energy is stored during line time and released during flyback. The secondary outputs are as follows: (a) 0.84V r.m.s. isolated heater supply; (b) line blanking pulse (a replica of the converter drive waveform); (c) 22V, rectified and applied to the video amplifier; (d) 128V, rectified and delivered to a 28V stabiliser supplying the tuning potentiometer RV1; (e) 182V (two windings) supplying the line integrators; (f) 268V, rectified and applied to the frame amplifiers and tube pin 5 (A2) via the focus potentiometer RV6; (9) 493V for the Cockcroft Ladder delivering the following EHT tube supplies either directly or via potential dividers: (i) 960V to A1 and A3, (ii) 960V to frame plates (+/ 40V variation on one plate using VERTICAL SHIFT potentiometer RV4); (iii) 1186V to line plate (1), 1060V to line plate (2) with a +/-50V variation using HORIZONTAL SHIFT potentiometer RV3 (asymmetry in the line plate voltages takes into account a natural shift in the tube); (iv) 2400V to the screen; (v) 1920V to the guard band; (vi) 1440V to the repeller. CIRCUIT OPERATION 3.1 Documentation 3.1.1 Two models of FTV1 have been sold in UK and Europe—FTV1B incorporating Issue 10 printed circuit board and the later model FTV1C using Issue 12 board. These appear identical from the outer case but the model identification code (B or C) is included in the serial number, located underneath the hinged stand on the back of the case. 3.1.2 The European model FTV2 is a version optimised to receive VHF/UHF in most European countries (except France) and is recognisable by a 3-position slide switch on front of case. 3.1.3 The build standard of a unit is traced via the serial number. Appropriate circuit diagrams, component layout diagrams, test point diagrams and parts lists for FTV1B and FTV1C (Issue 10and 12 p.c.b.) are included as annexes to this manual. Further copies are available from Timex Corporation, Harrison Road, Dundee. 3.2 Line Integrators 3.2.1 Both models of the receiver employ identical line integrators TR5 through TR9. The integrator has complementary stages, which derive the familiar saw tooth scanning waveforms for the line plates. Considering one half only, integrator TR9/C5 is charged during the line flyback by the positive pulse from L2 via D7. Over the same period TR7 holds off TR9, maintaining the charge on C5. At the end of flyback, the integrator discharges via TR6 at a rate determined by the picture width potentiometer and the stair-step line correction waveform applied to TR6 base. The correction waveform compensates for non-linearity in the tube's line scan characteristic, causing the integrator discharge rate to increase as the line progresses. The resultant output at TR9 is a.c. coupled to the line plate via C7. 3.2 2 She process is mirrored by are negative integrator, TR8, C4 which charges from negative flyback pulse via D6. However since TR8 tends to possess a larger inherent capacitance, the value of C4 is lower than its counterpart C5, thus ensuring a symmetrical scan. 3.3 Frame Amplifiers 3.3.1 The frame amplifier is a simple co-linear amplifier TR10, TR11 fed with complementary frame drive waveforms from the IC. The waveforms are 50Hz ramps with a small proportion of the 15kHz line scan waveform added to compensate for the non-linear frame scan characteristics of the tube. 3.3.2 Capacitor C21 improves the frequency response of the amplifiers compensating for the cumulative effects of capactive loading. Since the 15kHz correction waveform is most adversely affected by the gain characteristics, the value of C21A (select-on-test) in parallel with C21 must be carefully selected to obtain a linear scan. Too little capacitance causes the picture to taper left to right: too much causes a 'fishtail' effect (slewrate limiting). 3.3.3 The general gain characteristic of the amplifier is controlled by RV5 allowing the picture height to be adjusted. Note that this also alters the time constant of C21/21A and hence the compensating effect. 3.4 IC and Supporting Circuits 3.4.1 Pin-out details of the ICandoperation of the supporting circuits are summarised in the following paragraphs. In general wave shapes are shown on the circuit diagrams and in the oscillograms reproduce in Section 4. 3.4.2 Pin 1 (VCO Decouple). C32 decouples the control voltage to the sound local VCO. RV9 supplies a d.c. offset allowing the oscillator to be fine tuned for optimum sound quality. 3.4.3 Pin 2 (VCO Control). This is similar to pin 1 but affects the line hold VCO. RV8 allows the line hold to be adjusted. 3.4.4 Pin 3 (1n-Lock Detector). R31/C34 are bias components for the in lock detector. 3.4.5 Pin 4 (Line Correction). This feeds the line integrators with a stair-step waveform, which compensates the line scan for non-linearity in the tube. 3.4.6 Pins 5, 10 (ground), and 12 (VCC). These carry the 6V battery/adapter supply via ON/OFF switch S1. A battery voltage sensor automatically adjusts the line and frame scans as the battery level drops. 3.4.7 Pin 6 (Converter Drive). This feeds a pulse waveform to the power converter switching transistor TR4. The resultant output pulls current through the primaries of L1/L2 generating the unregulated d.c. power rails and the line blanking waveform for the tube. 3.4.8 Pins 7 and 8 (Frame Drives). These feed complementary frame scan waveforms to the frame amplifier TR10/TR11. The scans are compensated by the addition of a 15kHz line scan component which results in a 'bow tie' waveform seen in the oscillogram at the beginning and the end of the 50Hz ramp. 3.4 9 Pin 9 (3.2V). This feeds a temperature compensated, drift free d.c. supply to the line hold and sound offset potentiometers. 3.4.10Pin 11 (Loudspeaker). This is the output from the audio power amplifier, and is fed to the internal loudspeaker via a coupling capacitor C42 and the earphone socket. The latter has a 47 ohm resistor R37 connected to ground, providing the amplifier with short-circuit protection. 3.4.11 Pins 13 and 15 (Audio Amplifier). An external virtual earth amplifier is connected between the sound discriminator (Pin 15) and audio power amplifier input (Pin 13). The amplifier has a maximum gain of 10 adjusted by the VOLUME potentiometer RV2. C39 at Pin 15 provides de-emphasis. R35 provides supply noise cancellation. 3,4.12 Pin 14. This is the 3V d.c. varicap tuner supply. 3.4.13Pin 16 (Video). This is the output from the video detector and is fed to an external common emitter amplifier stage TR2. The mean amplitude of the video applied to the tube grid, and therefore the contrast, is fixed by the IC. 3.4.14Pin 17 (AGC Capacitor). This pin carries the AGC decoupling capacitor C28 for the IF amplifier. 3.4.15Pins 18 and 19 (IF Ground and IF). These pins carry the 230MHz IF signal from the tuner. 3.4.16 Pin 20 (Sync Separator). This carries the video signal from Pin 16 to the sync separation circuits in the IC via a filter R32, C38. The circuit is biased from the tuning supply via R41. 3.4,17 Pins 21 and 22 (Phase Filter). These pins connect a low pass filter (C29—C31 and R28) in the line hold phase locked loop. Shorting out the pins allows the oscillator to run at the natural frequency, adjusted using the line and hold potentiometer RV8. SETTING-UP PROCEDURES 5.1 Precautions WARNING EHT voltage up to 2.4kV are present in the FTV. Exercise extreme care when working on the exposed power-up p.c.b. ELECTROSTATIC SENSITIVITY FTV chassis incorporate electrostatic sensitive devices (ESDs). Special ESD handling methods must be used (e.g. BS 5783). IMPORTANT NOTE Setting up must never be carried out on returned FTVs without first checking for obscure faults which could have caused change of set up. see Table 4. 5.2 Setting-up involves checking the current consumption and various power supply voltages, selection of C21A, and alignment of the potentiometers. To carry out these procedures it is necessary to de-case the FTV (see 4.2). 5.3 For repair purposes, the complete setting-up procedure may not be necessary, depending on the nature of the fault. However, if any picture alignment potentiometer adjustments are necessary, then the complete picture alignment procedure must be followed as they interact to some extent (see Table 1). If a potentiometer is replaced it is important to set it initially to the mid position. 5.4 Current and Voltage Checks 5.4.1 When measuring the current consumption and voltages, the FTV must be locked onto a test signal with the volume (sound) control on minimum. If the FTV will not lock or is slow and difficult to lock, check that RV8 (line hold adjuster) is set correctly. Short circuit I.C. pins 21 and 22 and adjust for near stationery picture. 5.4.2 Using the specified supply voltage (5.9V +/—0.05V d.c., calibrated daily) check that the overall current consumption is within the specified limit. (95mA.max. for Issue 10 and 12; and 105mA.max. for Issue 2A, at minimum volume). 5.4.3 Check the following internally generated voltages are in accordance with those values as listed below: (a) EHT (TP8), using 1000 megohm probe; 2400 +/- 50v (b) Frame (TP9), using 1000 megohm probe; 268 +/- 9v. (c) Tuning Supply (TP7) w.r.t. 3V rail; 27.5 +/- 2v (d) Video Supply (TP6); 22.0 +/- 1.5v (e) Reference 3v Supply; 3.0 +/- 150millivolts (f) Heater Supply (True R.M.S.); 0.84 +/- 50millivolts In general, if these voltages are correct then the corresponding dependent voltages will be correct. 5.4.4 if the EHT is not correct, readjust by means or L1 and L2 and repeat current and voltage measurements. However, incorrect EHT is usually an Indication of a fault and readjustment will probably obscure rather than eliminate the cause. L1 and L2 interact greatly and must be tuned by approximately the same amount (same height of slug} to set the EHT. It is important to increase the EHT slowly and carefully because if it is allowed to go too high, various components notably D6) will fail. 5.5. Adjustment 5.5.1 The adjustment procedure requires that the FTV is locked onto the crosshatch pattern generated by a Phillips No. 5519 (or equivalent) Pattern Generator. An oscilloscope is also required to monitor IC pin 15 (TP15) with suitable sound carrier to set RV9. 5.5.2 Loosely couple RF Test signal to Aerial on Microvision and when setting the geometry, it is important that the FTV is not affected by any spurious magnetic fields, e.g. adjacent steel benches, pillars, girders, etc. 5.5.3 Table 1 sets out the order in which setting up should be done and explains how to adjust each potentiometer and select the S.O.T. capacitor C21A. FAULT DIAGNOSIS AND REPAIR 6.1 This chapter is a guide to the fault diagnosis and repair of the FTV1 and FTV2A, Knowledge of electronic theory and experience of servicing and fault finding are assumed. The following major equipment items are the minimum required: (a) Phillips Pattern Generator 5519 (or equivalent); (b) 4.7 to 6.5V variable power supply with 150mA current limit; (c) oscilloscope with rise time of < 1us; (d) oscilloscope probe x10 (10 megohm); (e) general purpose multimeter; (f) high voltage multimeter probe with impedance minimum 1000 megohms total, capable of measuring 3kV; (g) Normal Anti-static protection is recommended for handling Microvisions; (h) earthed soldering iron; (i) true R.M.S. meter (to check heater voltage). 6.2 As a matter of course, the unit should be visually inspected for obvious damage, prior to powering up. DO NOT APPLY POWER if the CRT is broken. 6.3 Note that care should be taken if there is a necessity to repair broken tracks, particularly in High Voltage areas where such repairs are not recommended. 6.4 Before a suspect unit is powered up, an initial check should be made between each power rail and OV to isolate any short circuits as shown in Table 2. 6.5 Power up the unit with 5.9V supply, current limited to 150mA, and carry out the voltage checks set out in Table 3. 6.6 Typical Waveforms 6.6.1 Examples of typical waveforms are given in Figures S1 to S20. It has been found that the best method of checking waveforms and response levels is to compare with the same point on a known good unit. Alternatively, the use of signal tracing equipment should identify a fault. 6.6.2 The waveforms shown were measured on a tuned unit locked to a pattern. The oscilloscope used for the measurements was equipped with a 10 megohm x10 probe. The reference on the figures (e.g. S1) refer to oscilloscope measuring points. 6.7 Fault Finding Guide 6.7.1 Table 1 is a fault diagnosis chart providing guidance to possible courses of action to follow when faults are identified. The order of symptoms is random and the list is as exhaustive as possible at the time of writing. TABLE 1 - AID TO FAULT DIAGNOSIS CONDITION LIKELY CAUSE RECOMMENDED ACTION Insufficient width including TR5 to TR9, C5, D6/7 Tube Check suspect comps, coils. Iinks, C6/7. white line at side of picture IC1 R5/29 and PCB contamination monitor S7,13, 15 with scope. Insufficient height including TR10,11, Tube, IC1, D8 Check suspect comps., R23/24 for correct corners folded over value, check frames supply and links. Monitor S3, 4, 5, 6 No picture (sound OK) Tube, IC1, TR2 Visually check heater's AC on TP4-5. Check converter S10 No sound (picture OK) Speaker, TR1, C41/42 Check connections, and earphone sound No ear. sound (speaker OK) SK2, R37 Check for faulty socket. Insensitivity to signals IC1, Tuner Check tracks tuner to IC1. Check aerial and wire routing along ledge of case. No picture or sound Volume On/Off switch Check switch, SK1 and battery. If converter is heard whistling check as for no picture/sound. Picture broken up, jagged jumpy Tube Use insulated screw driver and tap tube contacts gently for intermittence; Check short R3/R5 No picture shift adjustment RV3/4 Tube Check suspect comps. including R8, 9, 10, 11, 16 Cannot Focus RV6, Tube Check RV6, R14, 15, CRT pin 5(A2). Trapezoidal picture C21, 21a, EHT (D8-17) Check C21, 21a, EHT, contamination on PCB Frame cct. causing tracking. Fishtail picture C21, 21a Check R20, 21, 23, 24, reduce C21a Dim picture EHT (D8-17), CRT, R1 Check EHT, R1 value. If focus also then change CRT. Picture bright and washed out C1, R1, CRT Check leakage/short on C1 and value of R1 Streaky picture C1, CRT Check o/c on C1 Poor sound Speaker, IC1, RV9 Check speaker cone for swarf or inversion, check RV9 setting. Sound on vision C47, IC1, RV9 Check RV9 setting. O/c C57, IC1 in socket firmly. Shadina (corners dark) CRT and EHT Don't confuse with foldover. Check using RV3. Horizontal bright line on screen IC1, D8 Check for scan at IC pins 7-8. Picture large and distorted EHT, D9-17, C8-16, CRT Check PCB contamination, also on EHT stack Vertical line or short line scan D6, 7, C6, 7 PCB contamination under C6, 7. Check and renew as necessary. TV cuts out after prolonged use IC1 Renew TV drifts off tune C26 Check contamination under C26 It should be noted that the above fault finding table applies to Issue 12 version. For other versions the appropriate component numbers should be substituted. TABLE 2 - PICTURE SET UP PROCEDURE NOTE: Picture may shift slightly depending on Microvision orientation relative to the Earth’s magnetic field, therefore to obtain consistency, Microvision should be set up then orientated to ensure magnetic effect on picture shift is minimal. COMP FUNCTION ADJUSTMENT RV8 Line Hold Short TP1/TP2 to achieve min. motion of image, then remove short RV3 Horizontal Shift Adjust for horizontal centering of circle RV4 Vertical Shift Adjust for vertical centering of circle RV5 Height Adjust for optimum picture height RV7 Width Adjust for optimum picture height C21a Horizontal Taper Select C21a to adjust line taper to within spec. limits. Reset RV5 if necessary RV6 Focus Adjust for best compromise between focus in centre and lower corner furthest from gun, with emphasis on centre focus. Reset RV3, 5, 5, 7 if necessary (*) RV2 Volume Check on/off function and range of control RV9 Sound Offset Adjust as follows: Use spec. signal with sound carrier alternating between 6.0 and 5.532125 MHz and monitor IC pin 15(TP15) with oscilloscope. Set RV9 for 1.1v pk- pk signal, the 6MHz portion of signal should be the lower RV 1 Tuning Check for travel over full range receiving channels 21 and 69 [(*) NB. In scanning this, the Focus Adjustment reads RV3,5,5,7 in the original document] TABLE 3 - INITIAL SHORT CIRCUIT TESTS WITHOUT POWER Check continuity between test points and -ve battery terminal. CIRCUIT UNDER TEST TEST POINT Heater supply TP 4 Frame Supply TP 9 EHT Supply TP 8 +3V Supply TP 14 Tuner Supply TP 7 Video Supply TP 6 Battery Supply Battery +ve