Folge dem Video um zu sehen, wie unsere Website als Web-App auf dem Startbildschirm installiert werden kann.
Anmerkung: This feature may not be available in some browsers.
Yes , sorry for this . I use here V 1.99 and all works now . Sometimes i can't test all parameter .Hallo Rolf und Andre.
v 1.97 had the fx section freezed out. v.199 is now everything working supersmooth again.
I have created a local ebay for my Jeannie, just for pickup...
Want to see if I find someone interested in it, then I will buy another one!
Tnks for the constant updates! I have modified a computertalk to sound very much like
a MicroFreak, just severl voices better
I think a capacitative key like that of the Microfreak in a plug'in design like the Roland Boutique, if someone wanted to add one or two octave keyboard, it would be really cool, maybe a little bit smaller??? Tchusssss!
Noch eine kleine Kostprobe von der Jeannie mit Supersaw Oszillator.
Osc1+2 leichtes detune und Chorus2 mittlere Lautstärke.
Jeannie macht den Sound alleine.
Auf Tubeohm.com wird von „Superwave function“ in der 2er Version geschrieben - hier von Supersaw. Kann mir jemand die Begriffe kurz erläutern?
// Supersaw
case WAVEFORM_SAWTOOTH:
for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) {
saw_inc32 += 2039 * SupersawSpreadA;
uint32_t spread_2 = saw_inc32;
uint32_t spread_3 = saw_inc32 << 1;
uint32_t spread_4 = saw_inc32 << 2;
uint32_t spread_5 = saw_inc32 << 3;
uint32_t ph_1 = phasedata[i];
uint32_t ph_2 = (ph_1 + spread_2);
uint32_t ph_3 = (ph_1 + spread_3) >> 1;
uint32_t ph_4 = (ph_1 + spread_4) >> 2;
uint32_t ph_5 = (ph_1 + spread_5) >> 3;
int16_t val_1 = signed_multiply_32x16t(magnitude * Supersaw_gain1A, ph_1);
int16_t val_2 = signed_multiply_32x16t(magnitude * Supersaw_gain2A, ph_2);
int16_t val_3 = signed_multiply_32x16t(magnitude * Supersaw_gain2A, ph_3);
int16_t val_4 = signed_multiply_32x16t(magnitude * Supersaw_gain2A, ph_4);
int16_t val_5 = signed_multiply_32x16t(magnitude * Supersaw_gain2A, ph_5);
*bp++ = val_1 + val_2 + val_3 + val_4 + val_5;
}
break;
On the basis that you are unlikely to get at least 50 pre-orders for metal cases, can you publish the vector file that has been provided to PlexiLaser (Mr. Schon)?It's even more expensive than having a whole case made right away.
A metal case would cost between 70..80 €.
The question is how many people would buy it here since I have to pre-finance at least 50 cases.
G
Andre'
Kann auf Tubeohm.com keinen Hinweis finden. Wo genau ?
It is only for the panel . This is the File i use for Plexilaser. Can be PDF or ESP .On the basis that you are unlikely to get at least 50 pre-orders for metal cases, can you publish the vector file that has been provided to PlexiLaser (Mr. Schon)?
I would like to make my own top panel, but the PDF file posted here is not adequate.
Thank-you
thanks Andre,It is only for the panel. This is the File i use for Plexilaser. Can be PDF or ESP .
Have you ask him ??
// Supersaw
case WAVEFORM_SAWTOOTH:
uint16_t phase_spread = (inc & 0x0000FFFF) * SupersawSpreadA >> 10;
uint32_t phase_increment = inc & 0x000000FF;
uint16_t increments[3];
for (uint8_t i = 0; i < 3; ++i) {
phase_increment += phase_spread;
increments[i] = phase_increment;
}
for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) {
data_qs_phase[0] += increments[0];
data_qs_phase[1] += increments[1];
data_qs_phase[2] += increments[2];
uint32_t ph_1 = phasedata[i];
uint32_t ph_2 = (ph_1 + data_qs_phase[0]);
uint32_t ph_3 = (ph_2 + data_qs_phase[1]);
uint32_t ph_4 = (ph_3 + data_qs_phase[2]);
int16_t val_1 = signed_multiply_32x16t(magnitude * Supersaw_gain1A, ph_1);
int16_t val_2 = signed_multiply_32x16t(magnitude * Supersaw_gain2A, ph_2);
int16_t val_3 = signed_multiply_32x16t(magnitude * Supersaw_gain2A, ph_3);
int16_t val_4 = signed_multiply_32x16t(magnitude * Supersaw_gain2A, ph_4);
*bp++ = val_1 + val_2 + val_3 + val_4;
}
break;
Ist noch nicht 100 %tig wir arbeiten noch dran ....Das klingt doch inzwischen richtig klasse.
Falls es jemanden interessiert : Ich warte bei der Jeanni sehnsüchtig auf Unterstützung für Sustain-Pedal und MIDI-CC.
// Supersaw
case WAVEFORM_SAWTOOTH:
uint32_t phase_spread = (phase_increment >> 14) * SupersawSpreadA;
++phase_spread;
uint32_t saw_phase_increment = phase_increment & 0x000000FF; // add up 8bit random value
uint32_t increments[3];
for (uint8_t i = 0; i < 3; ++i) {
saw_phase_increment += phase_spread;
increments[i] = saw_phase_increment;
}
for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) {
data_qs_phase[0] += increments[0];
data_qs_phase[1] += increments[1];
data_qs_phase[2] += increments[2];
uint32_t ph_1 = phasedata[i];
uint32_t ph_2 = (ph_1 + data_qs_phase[0]);
uint32_t ph_3 = (ph_2 + data_qs_phase[1]);
uint32_t ph_4 = (ph_3 + data_qs_phase[2]);
int16_t val_1 = signed_multiply_32x16t(magnitude * Supersaw_gain1A, ph_1);
int16_t val_2 = signed_multiply_32x16t(magnitude * Supersaw_gain2A, ph_2);
int16_t val_3 = signed_multiply_32x16t(magnitude * Supersaw_gain2A, ph_3);
int16_t val_4 = signed_multiply_32x16t(magnitude * Supersaw_gain2A, ph_4);
*bp++ = val_1 + val_2 + val_3 + val_4;
}
break;
class AudioSynthWaveformModulatedTS : public AudioStream
{
public:
AudioSynthWaveformModulatedTS(void) : AudioStream(2, inputQueueArray),
phase_accumulator(0), phase_increment(0), modulation_factor(32768),
magnitude(0), arbdata(NULL), sample(0), tone_offset(0),
tone_type(WAVEFORM_SINE), modulation_type(0), syncFlag(0) {
}
void frequency(float freq) {
if (freq < 0.0) {
freq = 0.0;
} else if (freq > AUDIO_SAMPLE_RATE_EXACT / 2) {
freq = AUDIO_SAMPLE_RATE_EXACT / 2;
}
phase_increment = freq * (4294967296.0 / AUDIO_SAMPLE_RATE_EXACT);
if (phase_increment > 0x7FFE0000u) phase_increment = 0x7FFE0000;
}
void amplitude(float n) { // 0 to 1.0
if (n < 0) {
n = 0;
} else if (n > 1.0) {
n = 1.0;
}
magnitude = n * 65536.0;
}
void sync() {
syncFlag = 1;
}
void offset(float n) {
if (n < -1.0) {
n = -1.0;
} else if (n > 1.0) {
n = 1.0;
}
tone_offset = n * 32767.0;
}
void begin(short t_type) {
tone_type = t_type;
if (t_type == WAVEFORM_BANDLIMIT_SQUARE)
band_limit_waveform.init_square (phase_increment) ;
else if (t_type == WAVEFORM_BANDLIMIT_PULSE)
band_limit_waveform.init_pulse (phase_increment, 0x80000000u) ;
else if (t_type == WAVEFORM_BANDLIMIT_SAWTOOTH || t_type == WAVEFORM_BANDLIMIT_SAWTOOTH_REVERSE)
band_limit_waveform.init_sawtooth (phase_increment) ;
}
void begin(float t_amp, float t_freq, short t_type) {
amplitude(t_amp);
frequency(t_freq);
begin (t_type) ;
}
void arbitraryWaveform(const int16_t *data, float maxFreq) {
arbdata = data;
}
void frequencyModulation(float octaves) {
if (octaves > 12.0) {
octaves = 12.0;
} else if (octaves < 0.1) {
octaves = 0.1;
}
modulation_factor = octaves * 4096.0;
modulation_type = 0;
}
void phaseModulation(float degrees) {
if (degrees > 9000.0) {
degrees = 9000.0;
} else if (degrees < 30.0) {
degrees = 30.0;
}
modulation_factor = degrees * (65536.0 / 180.0);
modulation_type = 1;
}
virtual void update(void);
private:
audio_block_t *inputQueueArray[2];
uint32_t phase_accumulator;
uint32_t phase_increment;
uint32_t modulation_factor;
int32_t magnitude;
const int16_t *arbdata;
uint32_t phasedata[AUDIO_BLOCK_SAMPLES];
int16_t sample; // for WAVEFORM_SAMPLE_HOLD
int16_t tone_offset;
uint8_t tone_type;
uint8_t modulation_type;
int16_t syncFlag;
uint32_t data_qs_phase[3];
BandLimitedWaveform band_limit_waveform;
};